KR101504705B1 - An apparatus for manufacturing a molten iron - Google Patents

Abstract

The present invention relates to a multi-stage fluidized-bed reactor for reducing an iron-containing mixture obtained by mixing iron-containing ores in powdered or bulked general coal and powdered form with powdered iron, a compacting apparatus for producing powdered reduced iron as a hot compacted material, And a piping portion for maintaining a proper reduction ratio of the molten metal and the reduced iron to produce the molten iron from the sieve.

Description

TECHNICAL FIELD [0001] The present invention relates to an apparatus for manufacturing molten iron,

The present invention relates to a molten iron manufacturing apparatus provided with means for increasing the reduction efficiency of iron-containing ores in powder form.

The blast furnace law, which began in the 14th century, accounts for 60% of the world's iron production. However, the blast furnace method requires additional facilities such as a coke making facility and a sintering facility, such as a raw material pre-treatment facility in addition to a blast furnace, and the cost of processing the environmental pollutants generated in such an additional facility must also be taken into consideration, .

In order to solve the above-mentioned problems, a molten iron manufacturing apparatus and a method for manufacturing molten iron using the iron-containing ores of powder and granular coal and granular coal are disclosed. The apparatus for producing molten iron generally includes a multistage fluidized-bed reactor for reducing iron-containing ores in powder form, a high-temperature compacting apparatus for compacting the pulverized iron discharged from the fluidized-bed reactor, and a secondary- And a melting and gasifying furnace for melting the high-temperature compacted material discharged from the pyrolyzing apparatus and supplying the high-temperature reducing gas to the multi-stage fluidized-bed reactors. In addition, the molten iron manufacturing apparatus may further include an exhaust gas reforming circulation unit for mixing the high-temperature exhaust gas discharged from the melter-gasifier after cooling, compression, and CO2 removal by branching a part of the exhaust gas and further supplying a reducing gas to the multi- The device is initiated. Through this, reusing the reducing gas components such as CO and H2 present in the exhaust gas can reduce the consumption of the carbon materials in the process.

In general, the ore charged into the fluidized-bed reactor sequentially passes through the first reducing furnace, the second reducing furnace, and the final reducing furnace, while the reducing gas moves in the opposite order to the movement of the ore, and the ore of each fluidized- . Therefore, the degree of oxidation of the ore passing through the fluidized-bed reactor is affected by factors such as the degree of oxidation and temperature of the multiple-stage fluidized-bed reduction reactor internal reducing gas. In this case, the oxidation degree in the fluidized-bed reactor is defined as follows.

(%) = (Sum of CO and H2 concentrations in the reducing gas) / (sum of the concentrations of CO, CO2, H2 and H2O in the reducing gas) x 100

Particularly, in order to produce a stable molten iron, the optimum reduction ratio of the reduced iron discharged from the multi-stage fluidized-bed reduction reactor is known to be about 65%. In order to maintain the optimum reduction rate, the final reducing furnace and the fluidized- Lt; RTI ID = 0.0 > and / or < / RTI > temperature must be maintained thermodynamically within a range where metal iron can be stabilized.

However, in the case of the conventional multistage fluidized bed reactor, it is difficult to maintain the oxidation rate of the other fluidized-bed reactors connected to the upper end of the final reduction reactor in accordance with the reduction ratio of the minute-reduced iron because a reducing gas having a low oxidation degree is supplied only to the final reduction reactor. In this case, the reduction rate of the reduced iron discharged through the multi-stage fluidized-bed reduction reactor falls below the optimum reduction rate.

Further, in order to solve such a problem, when the exhaust gas (hereinafter referred to as modified exhaust gas) from which CO2 has been removed from the final reducing furnace is supplied, an excessive increase of the gas flow rate in the fluidized- And flow instability.

Based on the technical background as described above, the present invention is characterized in that a part of the reducing gas discharged from the final reducing furnace is diverged and discharged to the outside, the residual reducing gas is mixed with the reforming exhaust gas, And an optimum reduction ratio in the fluidized-bed reactor is maintained by supplying the molten iron to the furnace.

The apparatus for manufacturing molten iron according to one embodiment of the present invention includes: a multi-stage fluidized-bed reactor for reducing an iron-containing mixture in which powdered iron ore is mixed with powdered or massive coal; A compacting apparatus for producing the reduced iron in a high-temperature compacted material; A melting furnace for producing molten iron from the hot compacted material; And a piping unit for maintaining an appropriate reduction ratio of the minute reduced iron.

At this time, the multi-stage fluidized-bed reduction reactor may be a first reducing furnace that firstly reduces the iron-containing mixture in which the iron-containing ores of the common coal and the bulk are mixed, A second reducing furnace connected to the first reducing furnace and secondarily reducing the first reduced iron containing mixture; And a final reducing furnace connected to the second reducing furnace to finally reduce the secondary reduced iron-containing mixture.

At this time, the piping unit connects the final reducing furnace and the second reducing furnace in order to discharge a part of the reducing gas, which supplies the reducing gas discharged from the melting furnace to the multi-stage fluidized-bed reacting unit, to the outside A first branch conduit connected to branch to the first transfer conduit; A heat exchanger connected to the other end of the first branch conduit; a wet damper connected in series with the heat exchanger; A discharge pipe connecting the exhaust gas pipe and the wet silencer; An exhaust gas pipe for discharging the exhaust gas discharged from the multi-stage fluidized-bed reactors to the outside; A CO2 removing device for branching into the exhaust gas pipe to remove CO2 from the exhaust gas; And a reformed flue gas supply pipe connected to the reduction gas supply pipe to supply the reformed flue gas from which the CO 2 has been removed to the multistage fluidized-bed reduction reactor together with the reducing gas discharged from the melting furnace.

At this time, the discharge pipe may include a first flow rate control valve for controlling the amount of the reducing gas to be branched and discharging the branched reducing gas to the outside.

At this time, the piping section may include a second branch conduit branching to an exhaust gas supply pipe so that a part of the reformate exhaust gas passes through the heat exchanger.

At this time, the piping section may include a gas heater connected to the second branch conduit for heating the reformed flue gas.

At this time, the gas heater can be mixed with the oxygen supplied from the outside and the reforming exhaust gas in the gas heater and burned together.

In this case, the piping section may include a gas mixer connected to the gas heater, the second reducing furnace, and the final reducing furnace, respectively.

At this time, the gas mixer may be formed in a cyclone shape so that the reforming exhaust gas supplied from the gas heater and the reducing gas supplied from the final reducing furnace may be mixed and transferred to the second reducing furnace.

At this time, the gas mixer may be such that the pipe extending from the final reduction furnace is tangential to the gas mixer.

At this time, the second branch conduit may include a second flow control valve for regulating the amount of reforming exhaust gas passing through the heat exchanger.

In this case, the piping unit may include an installed gas concentration meter installed on one side of the pipe connecting the second reducing furnace and the first reducing furnace to sense oxidation degree of the mixed gas.

At this time, when the degree of gas oxidation of the gas concentration measuring device is equal to or more than the Fe stable region, the branched reducing gas is discharged through the first flow rate regulating valve and the reforming exhaust gas is discharged through the second gas- To be mixed with the branched reducing gas, and to supply the mixed gas to the second reducing furnace.

At this time, the first flow rate control valve and the second flow rate control valve can be interlocked so that the amount of the mixed gas supplied to the second reduction path is kept constant.

At this time, the supply amount and the discharge amount of the first flow rate control valve and the second flow rate control valve may be gradually adjusted.

The temperature of the reforming exhaust gas supplied to the heat exchanger may be the same as the temperature of the reducing gas exhausted through the exhaust pipe.

At this time, the temperature of the reducing gas discharged from the heat exchanger and flowing into the wet silencer may be 200 ° C or higher.

The apparatus for manufacturing molten iron according to an embodiment of the present invention adjusts the degree of oxidation of the reducing gas passing through the multi-stage fluidized-bed reactors to reduce the reduction ratio of the iron-containing mixture and the reduced iron through the multistage fluidized- Can be maintained.

1 is a manufacturing process diagram showing a molten iron manufacturing apparatus according to an embodiment of the present invention.
2 is a cross-sectional view of a gas mixer in accordance with an embodiment of the present invention.
3 is a plan view of a gas mixer in accordance with an embodiment of the present invention.
4 is a graph illustrating operating conditions of a multi-stage fluidized-bed reactor according to an embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings, which will be readily apparent to those skilled in the art to which the present invention pertains. The present invention may be embodied in many different forms and is not limited to the embodiments described herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and the same or similar components are denoted by the same reference numerals throughout the specification.

The term "on " in the present invention means to be located above or below the object member, and does not necessarily mean that the object is located on the upper side with respect to the gravitational direction.

The oxidation degree of the present invention is defined as follows.

(%) = (Sum of CO and H2 concentrations in the reducing gas) / (sum of the concentrations of CO, CO2, H2 and H2O in the reducing gas) x 100

1 is a manufacturing process diagram showing a molten iron manufacturing apparatus according to an embodiment of the present invention.

Referring to FIG. 1, an apparatus for manufacturing molten iron according to an embodiment of the present invention includes a multi-stage (multi-stage) apparatus 100 for reducing an iron-containing mixture in which powdered ore- A compacting apparatus 40 for producing the reduced-pitch iron as a high-temperature compacted compact, a melting furnace 60 for producing molten iron from the compacted compact at high temperature, and a low- And a piping section 70 for supplying the liquid.

As shown in FIG. 1, the iron-containing mixture in which the iron-containing ores in the form of powder or bulk is mixed with the iron-containing ore is sequentially passed through the three-stage fluidized-bed reactor 20 along the pulverized iron- Is reduced. At this time, the fluidized-bed reactor 20 includes a first reducing furnace 21 in which the iron-containing mixture is first reduced, a second reducing furnace 23 for reducing the primary reduced iron-containing mixture to second reduction, And a final reduction furnace (25) connected to the reduction furnace (23) by piping to finally reduce the secondary reduced iron-containing mixture to minute reduced iron.

The final reduced powder of reduced iron is formed into a compacted material through the compacting apparatus 40 and charged into the melting furnace 60. The configuration of the multi-stage fluidized-bed reactors 20, the compacting apparatus 40, and the melting furnace 60 of the present invention is already known, and a detailed description thereof will be omitted.

The piping unit 70 according to the embodiment of the present invention includes a reducing gas supply pipe 71, a first branch conduit P1, a heat exchanger 11, a wet dust collector 12, a discharge pipe 72, an exhaust gas pipe 73 A reforming flue gas supply pipe 74 and a second branch conduit P 2, a gas heater 13, a gas mixer 14 and a gas concentration measuring device 15.

The reducing gas supply pipe 71 is connected to the final reducing furnace 25 from the upper end of the melting furnace 60 to supply the hot reducing gas discharged from the melting furnace 60 to the final reducing furnace 25, As shown in FIG. Referring again to FIG. 1, the gas circulation and cooling apparatus H may cool a portion of the hot reducing gas discharged from the melting furnace 60 to control the temperature of the reducing gas supplied to the final reducing furnace 25 And may be branched to the reducing gas supply pipe 71.

A first transfer pipe (not shown) for transferring the reducing gas supplied through the reducing gas supply pipe 71 to the lower end of the second reducing furnace 23 is connected to the upper end of the final reducing furnace 25 according to an embodiment of the present invention. 75) can be connected. At this time, the upper end of the second reducing furnace 23 and the lower end of the first reducing furnace 21 may be connected to a second transfer pipe 79 for supplying the reducing gas. An exhaust gas pipe 73 for discharging the exhaust gas after the reduction reaction to the outside of the molten iron manufacturing apparatus 100 may be connected to the upper portion of the first reducing furnace 21.

1, the first branch conduit P1 is branched from the first transfer pipe 75 to discharge a part of the reducing gas discharged from the final reducing furnace 25 to the outside of the molten iron manufacturing apparatus 100 . The conduit of any one or more of the first transfer conduit (75) or the first branch conduit (P1) according to an embodiment of the present invention may be configured such that a refractory material for preventing damage to the conduit from the branched reducing high- May be formed to be lined.

On the other hand, the first branch conduit P1 is connected to the heat exchanger 11 so that the hot reducing gas can be cooled through heat exchange. At this time, the heat exchanger 11 can regulate the gas temperature in the molten iron manufacturing apparatus 100 through heat exchange between the gas passing through the heat exchanger 11.

The wet silencer (12) is connected in series with the heat exchanger (11) to control foreign matter such as dust and tar in the incoming reducing gas.

The discharge pipe 72 may be connected to the exhaust gas pipe 73 to discharge the reducing gas passing through the heat exchanger 11 and the wet dust collector 12 to the outside of the molten iron manufacturing apparatus 100. At this time, the discharge pipe 72 according to the embodiment of the present invention may be provided with a first flow rate control valve V1 for controlling the amount of the exhaust gas.

1, the CO2 eliminating device G is a device for removing a part of the exhaust gas discharged to the outside of the molten iron manufacturing apparatus 100, together with a reducing gas, to a multi-stage fluidized- 73, respectively. Through this, reformed flue gas with reduction efficiency can be produced by removing CO2.

1, the reformed flue gas supply pipe 74 is connected to the CO 2 removal device G to supply the reformed flue gas together with the reducing gas discharged from the melting furnace 60 to the multistage fluidized- And the reducing gas supply pipe 71 may be connected. The reduction efficiency of the reducing gas supplied to the final reducing furnace 25 can be increased.

Referring again to FIG. 1, the second branch conduit P2 may be branched from the reforming exhaust gas supply pipe 74 so that a part of the reformed exhaust gas can pass through the heat exchanger 11. At this time, the reformed flue gas introduced into the second branch conduit P2 can be heated inside the heat exchanger 11 by contacting with the high-temperature reducing gas introduced from the first branch conduit P1.

Referring again to FIG. 1, the gas heater 13 is connected to a second branch conduit P2 through the heat exchanger 11. The gas heater 13 according to an embodiment of the present invention reheats the incoming warming-up reforming exhaust gas. At this time, the gas heater may be mixed with oxygen that is blown from the outside and the reformed exhaust gas that has been heated, and burned together.

FIG. 2 is a cross-sectional view of a gas mixer according to one embodiment of the present invention, and FIG. 3 is a plan view of a gas mixer according to an embodiment of the present invention.

The gas mixer 14 according to an embodiment of the present invention may be connected to the gas heater 13, the second reducing furnace 23, and the final reducing furnace 25, respectively, as shown in Figs. 1 to 3 . At this time, the first transfer pipe 75 connects the reducing gas transfer pipe 76 connecting the final reducing gas passage 25 and the gas mixer 14, and the second gas pipe 14 connecting the gas mixer 14 and the second reducing pipe 23 A mixed gas transfer pipe 77 and a modified exhaust gas transfer pipe 78 connecting the gas heater 13 and the gas mixer 14. [

2 and 3, the reformed flue gas introduced from above the gas mixer 14 and the reducing gas introduced from the side of the gas mixer 14 are supplied to the gas mixer 14, And may be formed in a cyclone shape so as to form a rotating current therein and to be mixed with each other. At this time, the reduction gas transfer pipe 76 is connected to the circular mixer 14 of the gas mixer 14 viewed from the z-axis direction, as shown in FIGS. 2 and 3, 14). The reformed flue gas transfer pipe 78 may be connected to the upper center of the gas mixer 14 as shown in FIG. 3 so that the reformed flue gas transfer pipe 78 may be introduced into the reducing gas formed with the rotating current and uniformly mixed with the reducing gas .

On the other hand, a second flow control valve V2 may be installed on one side of the second branch conduit P2 in order to control the amount of the reforming exhaust gas passing through the heat exchanger 11. [ The amount of the reformed exhaust gas flowing into the heat exchanger 11 and the gas mixer 14 can be controlled.

Referring again to FIG. 1, a gas concentration meter 15 for detecting the degree of oxidation of the mixed gas flowing into the first reducing furnace 21 may be installed on one side of the second transfer pipe 79.

The construction of the apparatus for manufacturing molten iron according to one embodiment of the present invention has been described. Hereinafter, the operation of the apparatus for manufacturing molten iron according to one embodiment of the present invention will be described.

4 is a graph showing operating conditions of the multi-stage fluidized-bed reactor according to an embodiment of the present invention

Referring to FIG. 4, a graph showing the degree of oxidation and the temperature inside the multi-stage fluidized-bed reactor 20 on Fe or iron oxide stable region is shown as I or II. At this time, the section that steeply increases upward from the lower right end of FIG. 4 to the left is the oxidation degree and the temperature section in the final reduction reactor 25, and the section that gradually increases upward from the middle part of the graph to the left side is the second reduction path 23, And the oxidation degree and the temperature range in the first reducing furnace 21. [

 At this time, the thermodynamic stability condition of the reduced iron according to the degree of oxidation and the temperature of the multi-stage fluidized-bed reactor 25 is shown as I in the graph of FIG. That is, when the oxidation degree and the temperature are thermodynamically maintained in the Fe stable region, the reduction efficiency of the reduced iron is close to the optimum reduction ratio. At this time, the optimum reduction ratio may be 65% as shown in FIG.

However, when the first reducing furnace 21 and the second reducing furnace 23 deviate from the Fe stable region as shown in II of FIG. 4, the reduction efficiency of the reduced iron in the final reducing furnace 25 falls below the optimum reducing rate do.

Therefore, when the degree of oxidation of the mixed gas detected from the gas concentration measuring instrument 15 installed in the second transfer pipe 79 deviates from the Fe stable region as shown in II of FIG. 4, the first flow control valve V1 is opened A part of the reducing gas can be branched from the final reducing furnace 25 and discharged to the outside of the apparatus for manufacturing molten iron 100. [ At the same time, the second flow control valve V2 is opened to mix the reformed exhaust gas having a low oxidation degree with the reducing gas in the gas mixer 14, and supply the reformed exhaust gas to the second reducing furnace 23. As a result, the mixed gas having a high reduction efficiency is supplied to the second reducing furnace 23 and the first reducing furnace 21 so that the temperature and oxidizing conditions inside the multi-stage fluidized-bed reactor 20 are controlled to be Fe It can be adjusted to exist in the stable region.

The first flow control valve V1 and the second flow control valve V2 according to an embodiment of the present invention are used to control the amount of the reducing gas discharged to the outside of the branch and the molten iron manufacturing apparatus 100, So that the amount of the reforming exhaust gas supplied to the second reducing furnace 23 can be maintained constant. At this time, the reducing gas and the reforming exhaust gas may be adjusted so that a mutually constant amount is discharged or introduced in order to minimize fluctuation of the amount of the mixed gas supplied to the second reducing furnace 23. The reformed exhaust gas according to an embodiment of the present invention is supplied prior to the discharge of the reducing gas in order to prevent inactivation in the fluidized-bed reactor 20 due to abrupt change in the gas flow rate supplied to the second reducing furnace 23 .

Meanwhile, the temperatures of the reducing gas supplied to the heat exchanger 11 and the reducing gas discharged to the outside of the apparatus for manufacturing molten iron 100 through the discharge pipe 72 according to an embodiment of the present invention may be maintained to be equal to each other . At this time, when the temperature of the reducing gas introduced into the reforming exhaust gas and the heat-exchanged wet type dust collector 12 in the heat exchanger is less than 200 ° C, the tar component mixed in the reducing gas is condensed and the efficiency of the heat exchanger 11 Degradation or malfunction. Accordingly, it is preferable that the temperature of the reducing gas discharged from the heat exchanger 11 and flowing into the wet silencer 12 according to the embodiment of the present invention is 200 ° C or higher.

As described above, the apparatus for manufacturing molten iron according to one embodiment of the present invention reduces the degree of oxidation of the reducing gas passing through the multi-stage fluidized-bed reactors 20, The reduction ratio of the iron-containing mixture and the reduced iron can be maintained at an appropriate level.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

11: heat exchanger 12: wet dust collector
13: gas heater 14: gas mixer
15: gas concentration measuring instrument 20: multistage fluidized-bed reactor
21: first reducing furnace 23: second reducing furnace
25: final reduction furnace 40: compacting apparatus
60: Melting furnace 70: Piping section
71: Reduction gas supply pipe 72:
73: exhaust gas pipe 74: reformed exhaust gas pipe
75: first transfer pipe 76: reduction gas transfer pipe
77: mixed gas transfer pipe 78: reformed flue gas transfer pipe
79: Second conveying pipe 80: Minute reducing steel conveying pipe
100: The apparatus for manufacturing molten iron
G: CO2 removal device H: Gas circulation cooling device
P1: first branch conduit P2: second branch conduit
V1: first flow control valve V2: second flow control valve

Claims (17)

A multi-stage fluidized-bed reactor for reducing an iron-containing mixture in which powdered ore-containing ore-containing iron-containing ores is mixed with common carbon and powder;
A compacting apparatus for producing the reduced iron in a high-temperature compacted material;
A melting furnace for producing molten iron from the hot compacted material; And
And a piping unit for maintaining an appropriate reduction ratio of the reduced iron,
The multi-stage fluidized-bed reactors
A first reducing furnace for reducing the iron-containing mixture mixed with the iron-containing ores of the above-mentioned powdered or massed general carbon and powder onto the iron-reduced iron;
A second reducing furnace connected to the first reducing furnace and secondarily reducing the first reduced iron containing mixture; And
And a final reducing furnace connected to the second reducing furnace to finally reduce the secondary reduced iron-containing mixture,
The piping section
A reducing gas supply pipe for supplying a reducing gas discharged from the melting furnace to the multi-stage fluidized-bed reactor;
A first branch conduit, one end of which is connected to branch to a first transfer pipe connecting the final reduction reactor and the second reduction reactor to discharge some of the reducing gas to the outside;
A heat exchanger connected to the other end of the first branch conduit;
A wet silencer connected in series with the heat exchanger;
An exhaust gas pipe for discharging the exhaust gas discharged from the multi-stage fluidized-bed reactors to the outside;
A discharge pipe connecting the exhaust gas pipe and the wet silencer;
A CO2 removing device for branching into the exhaust gas pipe to remove CO2 from the exhaust gas;
And a reforming flue gas supply pipe connected to the reduction gas supply pipe to supply the reformed flue gas from which the CO 2 has been removed together with the reducing gas discharged from the melting furnace to the multistage fluidized-bed reduction reactor. delete delete The method according to claim 1,
Wherein the discharge pipe includes a first flow control valve for regulating an amount of reducing gas branched from the first conveyance pipe and discharging a reducing gas branched from the first conveyance pipe to the outside. 5. The method of claim 4,
And the piping section includes a second branch conduit branching to the exhaust gas supply pipe so that a part of the reformed flue gas passes through the heat exchanger. 6. The method of claim 5,
Wherein the piping section comprises a gas heater connected to the second branch conduit for heating the reformate flue gas. The method according to claim 6,
Wherein the gas heater is externally supplied with oxygen and the reforming exhaust gas are mixed and burned together inside the gas heater. 8. The method of claim 7,
And the piping section includes a gas mixer connected to the gas heater, the second reducing furnace, and the final reducing furnace respectively by pipes. 9. The method of claim 8,
Wherein the gas mixer is formed in a cyclone shape so that the reformed exhaust gas supplied from the gas heater and the reducing gas supplied from the final reducing reactor may be mixed and transferred to the second reducing furnace. 10. The method of claim 9,
Wherein the gas mixer is connected in a tangential direction of the gas mixer with a pipe extending from the final reduction furnace. 11. The method of claim 10,
Wherein the second branch conduit comprises a second flow control valve for regulating the amount of reforming off-gas passing through the heat exchanger. 12. The method of claim 11,
And the piping unit includes a gas concentration meter installed on one side of the pipe connecting the second reducing furnace and the first reducing furnace to sense oxidation degree of the mixed gas. delete 13. The method of claim 12,
Wherein the first flow rate control valve and the second flow rate control valve are interlocked so that the amount of the mixed gas supplied to the second reduction path is kept constant. delete The method according to any one of claims 8 to 12 and 14,
Wherein the temperature of the reforming exhaust gas supplied to the heat exchanger is equal to the temperature of the reducing gas discharged through the discharge pipe. 17. The method of claim 16,
Wherein the temperature of the reducing gas discharged from the heat exchanger and flowing into the wet silencer is 200 ° C or higher.

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