The present invention relates to a method and an apparatus for producing molten iron and particularly to an improved method for efficiently producing molten iron having a high iron purity by heating and reducing an iron oxide source such as iron ore together with a carbonaceous reducing agent such as coal in a molten iron production process constructed by combining a moving hearth type reducing furnace and an iron melting furnace.
The inventors of the present invention developed a molten iron production method for, in a molten iron production process in which a rotary hearth furnace (moving hearth type reduction furnace) and a melting furnace (iron-melting furnace) are coupled, obtaining molten iron by feeding solid reduced iron to a melting furnace after heating and reducing a compact containing iron oxide and a carbonaceous reducing agent to the solid reduced iron having a metallization degree of 60% or higher in a rotary hearth furnace, and melting the solid reduced iron while controlling the secondary combustion ratio in the melting furnace to be 40% or lower by burning a carbonaceous material fed as a fuel with oxygen to melt the solid reduced iron. They also indicated that a part of or all of the carbonaceous material fed as the fuel into the melting furnace could be fed as a bedding carbonaceous material onto the hearth of the rotary hearth furnace (see Japanese Unexamined Patent Publication No. 2004-176170).
However, only qualitative actions and effects were indicated concerning the method using the bedding carbonaceous material, and specific operating conditions for further reducing the fuel specific consumption while stabilizing the operations of the rotary hearth furnace and the melting furnace were still uncertain. Thus, there was a room for improvement.
On the other hand, the inventors of the present invention also proposed a method for, in a process for producing metallic iron by feeding a raw material containing an iron-oxide containing substance and a carbonaceous reducing agent after laying a powdery bedding carbonaceous material for atmospheric adjustment on the hearth of the rotary hearth furnace, and heating the raw material in the furnace to reduce and melt the raw material, recycling the bedding carbonaceous material-discharged from the rotary hearth furnace to be used again in the rotary hearth furnace, thereby preventing such a phenomenon that the powdery bedding carbonaceous material is caked into a cracker-shaped material (see Japanese Unexamined Patent Publication No. 2003-213312).
However, the above process includes no melting furnace and produces the metallic iron only using the rotary hearth furnace, and physical and chemical properties required for the bedding carbonaceous material, the recycling conditions of the bedding carbonaceous material and the like cannot be applied as they are to the molten iron production process disclosed in the former prior art document in which the rotary hearth furnace and the melting furnace are coupled.
Accordingly, an object of the present invention is to provide a molten iron producing method which can further reduce the fuel specific consumption while stabilizing the operations of a moving hearth type reducing furnace and an iron-melting furnace in a molten iron production process constructed by combining the moving hearth type reducing furnace and the iron-melting furnace, and a suitable molten iron producing apparatus.
The present invention is directed to a molten iron producing method for producing molten iron using a molten iron production process constructed by combining a moving hearth type reducing furnace and an iron-melting furnace, comprising the following steps (1) to (4):
(1) reducing furnace charging step of charging a bedding carbonaceous material onto a hearth of the moving hearth type reducing furnace and placing carbonaceous-material composite agglomerates containing a powdery iron oxide source and a powdery carbonaceous reducing agent on the bedding carbonaceous material,
(2) reduction step of moving the hearth inside the moving hearth type reducing furnace, thereby heating and reducing the carbonaceous-material composite agglomerates to solid reduced iron and heating and drying the bedding carbonaceous material by distillation into char,
(3) melting furnace charging step of charging the solid reduced iron and the char into the iron-melting furnace without being substantially cooled, and
(4) melting step of blowing an oxygen-containing gas into the iron-melting furnace to melt the solid reduced iron into the molten iron.
According to the present invention, the hearth can be more securely protected by using the bedding carbonaceous material to avoid troubles such as the peeling of the hearth. Therefore, the moving hearth type reducing furnace can be continuously operated over a longer period of time. Further, since the char after devolatization contains no volatile content, the damage of the refractory by the combustion of the volatile content in the iron-melting furnace can be prevented, thereby extending the lift of the refractory of the iron-melting furnace. Further, the reoxidation of the solid reduced iron in the moving hearth type reducing furnace can be prevented by using the bedding carbonaceous material, whereby a high metallization degree of, e.g. 92% or higher, can be achieved and the carbonaceous material consumption in the iron-melting furnace can be considerably reduced.
As a result, the specific fuel consumption can be further reduced while the operations of the moving hearth type reducing furnace and the iron-melting furnace are more stabilized.
Hereinafter, the present invention is described in detail with reference to the drawings showing one embodiment thereof.
Iron ore “a” as an iron oxide source and coal b as a carbonaceous reducing agent are, if necessary, separately crushed into particles having diameters of approximately below 1 mm. The thus obtained powdery iron ore A as a powdery iron oxide source and powdery coal B as a powdery carbonaceous reducing agent are mixed at a specified ratio, a suitable amount of binder and/or a suitable amount of moisture are added if necessary (further, all or a part of an auxiliary raw material I as a slag forming agent to be added in the iron-melting furnace 16 may be added here), and these are mixed by a mixer 8. Thereafter, the mixed compound is granulated to have a particle diameter of about 6 to 20 mm in a granulator 11, thereby obtaining carbonaceous-material containing pellets D as carbonaceous-material composite agglomerates. It should be noted that a volatile content of the coal (carbonaceous reducing agent) b is desirably 30 mass % or lower because the carbonaceous-material containing pellets D are likely to burst upon being heated in the rotary hearth furnace 14 if the volatile content is excessively high.
The carbonaceous-material containing pellets D are preferably dried in a drier 13 until the moisture content thereof becomes 1 mass % or lower in order to prevent the bursting in the rotary hearth furnace 14.
(1) Reducing Furnace Charging Step
Subsequently, for example, coal as a bedding carbonaceous material E is charged onto a hearth 32 of the rotary hearth furnace 14 to have a specified thickness as diagrammatically shown in
As a means for charging the bedding carbonaceous material E onto the hearth 32 in this way (bedding charging means) can be used a means for quantitatively dispensing the bedding carbonaceous material E, for example, from an intermediate hopper disposed above the rotary hearth furnace 14 and feeding the dispensed bedding carbonaceous material onto the hearth 32 via a charging pipe, and dispersing the fed bedding carbonaceous material E along the width direction of the hearth 32 by means of a dispersion screw. As a means for placing the carbonaceous-material containing pellets D on this bedding carbonaceous material E (raw-material charging method) can be used a means having a construction similar to the bedding charging means, including an intermediate hopper, a charging pipe and a dispersion screw and disposed downstream from the bedding charging means with respect to a moving direction of the hearth 32.
The thickness of the bedding carbonaceous material E charged onto the hearth 32 is preferably 1 to 10 mm. If this thickness is below 1 mm, it is difficult to securely cover the entire outer surface of the hearth 32 and a reoxidation preventing effect may become insufficient. On the other hand, if this thickness exceeds 10 mm, an effect of heating the carbonaceous-material containing pellets D from their bottom surfaces via the outer surface of the hearth 32 is reduced and an amount of the carbonaceous material charged into the iron-melting furnace 16 becomes excessive, resulting in a higher possibility of increasing the fuel specific consumption. The thickness of the bedding carbonaceous material E is more preferably 2 to 5 mm.
The average particle diameter of the bedding carbonaceous material E is preferably 1 to 5 mm. If the average particle diameter is below 1 mm, the bedding carbonaceous material is likely to disperse upon being changed into the rotary hearth furnace 14 and the iron-melting furnace 16, thereby reducing a carbonaceous material yield. On the other hand, if the average particle diameter exceeds 5 mm, it is approximate to the upper limit of the preferable thickness of the bedding carbonaceous material E and it becomes difficult to lay the bedding carbonaceous material E at a uniform thickness. In addition, clearances between the carbonaceous particles become larger and the carbonaceous-material containing pellets D enter these clearances. Thus, it becomes difficult to uniformly bed the carbonaceous-material containing pellets D on the layer of the bedding carbonaceous material E, thereby increasing a possibility of leading to reductions in productivity and metallization degree. The average particle diameter of the bedding carbonaceous material D is more preferably 2 to 4 mm.
The crushed coal b may be sieved using a specified particle diameter (sieve mesh of, e.g. 1 mm) as a criteria, and the powdery material below the sieve may be used as the powdery carbonaceous reducing agent B and the one above the sieve may be used as the bedding carbonaceous material E.
The Giesler's maximum fluidity MF of the bedding carbonaceous material E preferably satisfies a relationship: log MF≦2. If log MF exceeds 2, the carbonaceous particles are excessively softened and molten upon being heated in the rotary hearth furnace 14 and deposit is likely to be formed on the hearth 32. The Giesler's maximum fluidity MF more preferably satisfies a relationship: log MF≦1.
The volatile content of the bedding carbonaceous material E is preferably 10 mass % or higher by dry weight. This is because coal such as anthracite coal having less volatile content has a high apparent density due to its dense structure and is likely to burst to be powdered despite its less volatile content.
The volatile content of the bedding carbonaceous material E is preferably 50 mass % or lower, more preferably 40 mass % or less by dry weight. The volatile content in the bedding carbonaceous material E is almost completely devolatized upon being heated in the rotary hearth furnace 14, and can be used as a fuel gas in the rotary hearth furnace 14. However, if the volatile content is excessive, more combustible gas than necessary is produced from the bedding carbonaceous material at an initial stage of reduction in the rotary hearth furnace 14 and the unconsumed combustible gas is discharged while of 6 min., more preferably 8 min. This causes the carbonaceous-material containing pellets D to be heated in the rotary hearth furnace 14, whereby the iron oxide in the carbonaceous-material containing pellets D is reduced by the carbonaceous reducing agent to be metallized, thereby becoming solid reduced iron F. The metallization degree of the thus obtained solid reduced iron F is 92% or higher, and the carbon content thereof is preferably 10 mass % or lower, more preferably 5 mass % or lower. On the other hand, the bedding carbonaceous material E is heated in the rotary hearth furnace 14 to have the volatile content thereof devolatized (dried by distillation), thereby becoming char G. The devolatized volatile content is burnt in the rotary hearth furnace 14 to be effectively used as a fuel. As a means (heating means) for heating the carbonaceous-material containing pellets D and the bedding carbonaceous material E can be used, for example, a plurality of burners (not shown) disposed at an upper part of the side wall of the rotary hearth furnace 14.
If the atmospheric temperature is 1350° C. or higher, the carbonaceous-material containing pellets D are molten on the hearth 32 to be separated into iron components and slag components. Since the carbonaceous-material containing pellets D are difficult to discharge from the rotary hearth furnace 14 while being molten, they are discharged after being cooled and solidified in the rotary hearth furnace 14. The solid reduced remaining in the exhaust gas from the rotary hearth furnace 14, which leads to a reduced energy efficiency. Further, if the volatile content is excessive, the carbonaceous material becomes lighter due to the devolatization of the volatile content caused by heating and is likely to scatter upon being discharged from the rotary hearth furnace 14, thereby leading to a reduced carbonaceous material yield. The bedding carbonaceous material E is desirably dried before being charged into the rotary hearth furnace 14. A carbonaceous material whose volatile content is about 50 mass % or higher like brown coal is dried, it becomes porous and easier to ignite and, therefore, is difficult to handle.
It is not necessary to use only one kind of bedding carbonaceous material having the above preferable amount of the volatile content, and two or more kinds of carbonaceous materials having different amounts of volatile contents may be used by being suitably mixed. Carbonaceous materials already heat-treated in a separate process such as coke powder or petroleum coke may be used as the one to be mixed.
(2) Reduction Step
The carbonaceous-material containing pellets D and the bedding carbonaceous material E placed in layers on the hearth 32 in this way are caused to pass inside the rotary hearth furnace 14 heated at an atmospheric temperature of 1100° C. to 1450° C., more preferably 1250° C. to 1450° C. for a residence time iron F in this case is a mixture of powdery iron and solid slag. However, it is not preferable from a viewpoint of the productivity and the energy efficiency of the entire process to cool and solidify the pellets D molten in the rotary hearth furnace 14 and melt again in the iron-melting furnace 16. Accordingly, in order to further improve the productivity and the energy efficiency of the entire process, it is desirable to discharge the carbonaceous-material containing pellets D from the rotary hearth furnace 14 before being molten on the hearth and melt them in the iron-melting furnace 16 while improving the productivity in the rotary hearth furnace 14 by setting the atmospheric temperature at 1350° C. or higher during the reduction in the rotary hearth furnace 14.
In order to prevent the molten iron and the molten slag from damaging a hearth refractory in the case that the carbonaceous-material containing pellets D should be molten on the hearth 32, it is also effective to provide a layer of a carbonaceous material P for hearth protection, which is a fine carbonaceous material for preventing the permeation of the molten material between the hearth 32 and the bedding carbonaceous material E or a carbonaceous material P for hearth protection containing fine carbonaceous material as shown in
The metallization degree of the solid reduced iron F is set at 92% or higher and the carbon content thereof is preferably set at 10 mass % or lower, more preferably at 5 mass % or lower for the following reasons.
First, the reasons for setting the metallization degree at 92% or higher are given. Specifically, the higher the metallization degree of the solid reduced iron F, the less carbon amount is necessary to metallize iron oxide (FeO, etc.) remaining in the solid reduced iron F in the iron-melting furnace 16, wherefore the entire carbonaceous material consumption in the iron-melting furnace 16 can be reduced. Thus, it is desirable to maximally increase the metallization degree. However, if the carbonaceous-material containing pellets are reduced by the rotary hearth furnace without using the bedding carbonaceous material, the solid reduced iron is reoxidized by the oxidizing atmosphere in the rotary hearth furnace. Thus, it has been conventionally very difficult to stably obtain a metallization degree of 90% or higher as shown in
Next, reasons for setting the carbon content preferably at 10 mass % or lower, more preferably at 5 mass % or lower are given. Specifically, if the carbon content in the solid reduced iron F is high, it covers a carbon amount necessary to metallize iron oxide (FeO, etc.) remaining in the solid reduced iron F and the remaining carbon amount is used to carburize the molten iron obtained by melting the solid reduced iron. Thus, a higher carbon content is preferable from a viewpoint of the carbonaceous material consumption in the iron-melting furnace 16. However, the higher the carbon content (remaining carbon amount), the smaller the crushing strength of the solid reduced iron F as shown in
If liquid coal is used as the powdery carbonaceous reducing agent B to be contained into the carbonaceous-material containing pellets D, the carbon content can be increased to as high as about 10 mass % while maintaining the strength of the solid reduced iron F. However, since the liquid coal is not abound and generally expensive, it is desirable to use coal having no fluidity and employ a production method for reducing the carbon content in the solid reduced iron F to 5 mass % or lower.
Such metallization degree and carbon content of the solid reduced iron F can be obtained by suitably adjusting the mixing ratio of the iron ore (iron oxide source) “a” and the coal (carbonaceous reducing agent) b in the carbonaceous-material containing pellets D, the thickness and the average particle diameter of the bedding carbonaceous material E, the atmospheric temperature of the rotary hearth furnace 14, the residence time of the carbonaceous-material containing pellets D in the rotary hearth furnace 14, and other factors.
(3) Melting Furnace Charging Step
The solid reduced iron F and the char G thus obtained are preferably taken out of the rotary hearth furnace 14 and intermittently charged into the iron-melting furnace 16 while being hot (in other words, while being at high temperature or without being substantially cooled) As one example of such a melting furnace charging means, the following hopper and containers may be used.
Specifically, as shown in
Another carbonaceous material H (hereinafter referred to as “additional carbonaceous material”) to be added if the carbonaceous material consumption necessary in the iron-melting furnace 16 cannot be covered only by the auxiliary raw material I as the slag forming agent, the carbon content in the solid reduced iron F and the char G and the like (hereinafter referred to as “auxiliary raw material and other charged materials) is added in the iron-melting furnace 16 by a system different from the one for the solid reduced iron F and the char G. Since the solid reduced iron F, the char G, the auxiliary raw material and other charged materials adhere and deposit upon touching the inner wall surface of the iron-melting furnace 16, they are preferably charged in such a manner as not to touch the inner wall surface of the iron-melting furnace 16.
By charging the solid reduced iron F and the char G while being hot (being at high temperature or without being substantially cooled) in this way, solid sensible heat can be effectively recovered and the carbonaceous material consumption of the iron-melting furnace 16 can be reduced.
Further, by intermittently dispensing the solid reduced iron F and the char G and letting them drop in a mass into the iron-melting furnace 16 within a short period of time, a scattering rate of dust of the char G into an exhaust gas M can be reduced, wherefore the carbonaceous material yield in the entire process can be improved.
Specifically, if the solid particles made up of the solid reduced iron F and the char G are continuously charged as solid reduced iron has been conventionally continuously charged, there is a high probability that they separately drop because a solid mass feed rate per unit time is small. Thus, the char particles being lightweight and having small particle diameters are likely to get scattered into the exhaust gas by the flow of the gas produced from molten metal. Contrary to this, if the solid reduced iron F and the char G are intermittently charged together, the particles of the char G drop as aggregates together with other solid particles heavier and larger in particle diameter than the char because the solid mass feed rate per unit time is large. Thus, gas around the aggregates is caused to flow downward. As a result, the particles of the char G likely to scatter as single particles drop along the downward flow of the gas, wherefore the char particles prevail against the flow of the gas produced from the molten metal and added into the molten metal with a good yield without being scattered.
It is recommended to intermittently dispense the solid particles (solid reduced iron F and char G) (charge into the iron-melting furnace 16) at a frequency of 1 to 10 min., more preferably 2 to 5 min for the following reasons. Specifically, if the charging frequency is excessively increased, it becomes difficult to obtain the scatter preventing effect because the solid mass feed rate per unit time does not become sufficiently large. In addition, equipment troubles are likely to occur because the slide gate valve 107 is frequently opened and closed. On the other hand, if the charging frequency is excessively lessened, the scatter preventing effect is saturated. In addition, since a large amount of the solid reduced iron F and the char G are added at once, there arise problems that the iron-melting furnace 16 becomes difficult to control due to its large thermal fluctuation; the effect of recovering the solid sensible heat is reduced due to the temperature decreases of the solid reduced iron F and the char G upon being charged into the iron-melting furnace 16; and the capacity of the hopper 106 needs to be increased to thereby increase the plant cost.
The solid reduced iron F and the char G upon being charged into the iron-melting furnace 16 without being substantially cooled are made to have temperatures at which the solid reduced iron F and the char G discharged from the intermediate hoppers can be charged into the furnace 16 without causing thermal loads to the furnace 16 when being charged into the furnace 16, specifically 500° C. to 1100° C.
For the following reasons, it is preferable that the temperatures of the solid reduced iron F and the char G upon being charged into the iron-melting furnace 16 are 500° C. to 1100° C. If the temperatures are below 500° C., the effect of recovering the solid sensible heat is small. On the other hand, if the temperatures are above, 1100° C., the heat resistance of the discharge screw and the like become problematic and operation troubles are likely to occur.
If the carbonaceous material consumption necessary in the iron-melting furnace cannot be covered only by the carbon content of the solid reduced iron F and the char G, the additional carbonaceous material H may be additionally charged into the iron-melting furnace 16 as described above.
The average volatile matter content in all the carbonaceous material to be charged into the iron-melting furnace 16 (excluding carbon contained in the solid reduced iron F) is preferably 15 mass % or lower by dry weight. In the case of charging the additional carbonaceous material H, it is desirable to choose the kind of coal such that an average volatile matter content which is a weighted average of the volatile content of the additional carbonaceous material H and that of the char G (normally about 0 mass %) is 15 mass % by dry weight. If the average volatile matter content exceeds 15 mass %, gas-phase temperature excessively increases due to the combustion of the volatile content in the iron-melting furnace 16, thereby increasing a risk of damaging the refractory.
(4) Melting Step
The solid reduced iron F is molten to separate slag L by blowing an oxygen gas J as an oxygen-containing gas into the iron-melting furnace 16 by means of a plurality of lances as an oxygen blowing means to burn the carbonaceous material (char G, additional carbonaceous material H), whereby molten iron K can be obtained. It should be noted that the iron-melting furnace 16 may be of the inclining type or of the fixed type.
In this melting step, it is preferable to perform the melting on the condition of a secondary combustion ratio of 40%. If the secondary combustion ratio exceeds 40%, the effect of reducing the carbonaceous material consumption can be hardly confirmed when the metallization degree of the solid reduced iron F is 92% or higher. In addition, the gas-phase temperature excessively increases to increase a risk of damaging the refractory, thereby increasing loads on the iron-melting furnace 16. A more preferable range of the secondary combustion ratio is 10 to 40% at which the carbonaceous material consumption is sufficiently low, and a even more preferable range thereof is 15 to 30% at which the loads on the iron-melting furnace 16 are further reduced.
(5) Melting-Furnace Exhaust Gas Circulating Step
Since the exhaust gas (melting-furnace exhaust gas) M in the iron-melting furnace 16 contains high concentrations of CO and H2 components, it is desirable to feed at least a part of the exhaust gas M to the rotary hearth furnace 14 after cooling it and removing dust therefrom in a gas cooling/dust removing apparatus 24 and to use the exhaust gas as a fuel gas for the rotary hearth furnace 14 by adding an external fuel N if necessary.
As described above, according to the first embodiment, the hearth 32 is securely protected by using the bedding carbonaceous material E, thereby avoiding troubles such as the peeling of the hearth, with the result that the rotary hearth furnace 14 can be continuously operated over a long period of time. Further, the volatile content that is devolatized when the bedding carbonaceous material E is heated in the rotary hearth furnace 14 is effectively used as the fuel gas for the rotary hearth furnace together with at least a part of the exhaust gas, wherefore the fuel consumption of the rotary hearth furnace 14 can be reduced. Since the char G after the devolatization contains no volatile content, a damage of the refractory caused by the combustion of the volatile content in the iron-melting furnace 16 can be prevented, thereby extending the life of the refractory of the iron-melting furnace 16. Further, the reoxidation of the solid reduced iron F in the rotary hearth furnace 14 can be prevented by using the bedding carbonaceous material E, thereby achieving a high metallization degree of 92% or higher to considerably reduce the carbonaceous material consumption in the iron-melting furnace 16. The entire process including the reduction and the melting can be made into an energetically self-contained process by adjusting the metallization degree of the solid reduced iron F, the consumed amount of the bedding carbonaceous material, and the amount of the volatile content of the bedding carbonaceous material E to conform the total heat quantity of the exhaust gas produced from the iron-melting furnace 16 to the heat quantity necessary and sufficient in the rotary hearth furnace 14. Further, the rate of scattering fine particles of the char G and the like into the exhaust gas can be reduced to improve the carbonaceous material yield in the entire process by intermittently dispensing the solid reduced iron F and the char G and letting them drop in a mass into the iron-melting furnace 16 from above within a short period of time.
The following step (6) may be provided between the reduction step (the above step (2)) and the melting furnace charging step (the above step (3)).
(6) Step of Hot-Forming the Solid Reduced Iron F and the Char G Together while they are Hot
Specifically, the solid reduced iron F and the char G may be dispensed together, for example, from the hopper 106 while being hot, and pressure-formed into hot briquetted iron (HBI) by a hot forming machine, and this HBI may be dropped and charged into the iron-melting furnace 16 at a temperature of, e.g. 500 to 1100° C. without being cooled.
This prevents the fine particles from scattering at the time of being charged into the iron-melting furnace 16, and an amount of dust in the exhaust gas from the iron-melting furnace 16 can be considerably reduced. Therefore, an iron yield and a carbon yield can be considerably improved.
Since the purpose of forming here is to eliminate fine particles, the shape of the compacts is not limited to that of a briquette and the compacts may be plate-shaped aggregates or aggregates having irregular shapes. The compacts need not be strong unless they become fine particles again due to a handling impact until the charging into the iron-melting furnace 16.
The following steps (7) to (9) may be provided instead of the melting furnace charging step (the above step (3)).
(7) Hot-classifying step of classifying the solid reduced iron F and the char G into coarse particles and fine particles while they are hot or without being substantially cooled after the solid reduced iron F and the char G are taken together out of the rotary hearth furnace 14.
(8) Coarse particle charging step of gravitationally charging coarse particles into the iron-melting furnace 16
(9) Fine particle injection step of charging the fine particles into the iron-melting furnace 16 by injection
Specifically, facilities having the following construction may be employed. A screen having sieve meshes of about 2 to 5 mm is provided at a portion of the rotary hearth furnace 14 where the solid reduced iron F and the char G are discharged, and the solid reduced iron F and the char G are sieved while being hot, wherein course particles above the sieve and fine particles below the sieve are temporarily stored in separate intermediate hoppers. The coarse particles are charged into the iron-melting furnace 16 from above at a temperature of, e.g. 500° C. to 1100° C. by the gravitational drop. On the other hand, the fine particles are blown into the molten iron in the iron-melting furnace 16 and/or the molten slag formed on the molten iron via an injection lance and a tuyere provided at the furnace side of the iron-melting furnace 16 and/or at the bottom of the furnace using an inert gas such as N2 as a carrier gas.
Since this causes the fine particles to be trapped in the molten iron and/or the molten slag, the scattering of the fine particles can be prevented at the time of charging into the iron-melting furnace 16 and the amount of dust in the exhaust gas from the iron-melting furnace 16 can be considerably reduced similar to the second embodiment. Therefore, an iron yield and a carbon yield can be considerably improved.
The aforementioned melting step (4) is preferably performed as follows. Specifically, it is preferable to reduce a blowing rate of the oxygen gas (total blowing rate from a plurality of lances) at the time of charging the solid reduced iron F and the char G into the iron-melting furnace 16. This can reduce an amount of gas produced from the molten metal and further reduce the scattering amount of the char G.
In order to securely reduce the scattering amount of the char G, it is desirable to set the blowing rate (total amount) of the oxygen gas at the time of charging the solid reduced iron F and the char G at 80% or lower, more preferably 60% or lower of the blowing rate (total amount) of the oxygen gas when the solid reduced iron F and the char G are not charged. However, the blowing rate is desirably 30% or higher since the combustion in the furnace may stop if the blowing rate is excessively reduced.
In this case, out of the plurality of lances, the oxygen blowing rate(s), for example, from some (one or a plurality of) lance(s) disposed near the position where the solid reduced iron F and the char G are charged may be preferentially reduced or stopped. This enables a local and considerable reduction of the amount of the gas produced from the molten metal near the position where the solid reduced iron F and the char G are charged. Therefore, the scattering amount of the char G can be even more reduced.
Further, it is preferable to dispose a baffle plate 114 between a reduced iron charging opening 112, which is a charging portion for the solid reduced iron F and the char G, and an exhaust gas discharging opening 113, which is a discharging portion for the exhaust gas (melting-furnace exhaust gas) from the iron-melting furnace 16 at a ceiling portion 111 of the iron-melting furnace 16 as shown in
In this melting step as well, the melting is preferably performed on the condition of a secondary combustion ratio of 40% or lower. A more preferable range of the secondary combustion ratio is 10 to 40% at which the carbonaceous material consumption is sufficiently low, and an even more preferable range thereof is 15 to 30% at which the loads on the iron-melting furnace 16 are further reduced.
[Modifications]
Although the solid reduced iron and the char are intermittently charged into the iron-melting furnace together in the foregoing embodiments, they may be classified into the solid reduced iron and the char by a screen or the like while being hot after being taken out from the rotary hearth furnace and may be separately charged into the iron-melting furnace. In this case, it does not matter whether the solid reduced iron is charged continuously or intermittently, but the char is intermittently charged. However, it is more preferable to charge the char together with the solid reduced iron as in the first embodiment rather than to separately charge the char since the solid mass feed rate per unit time is larger in the former case and the scattering of the char can be more securely prevented.
Although the auxiliary raw material and the other charged materials are added into the iron-melting furnace by the system different from the one for the solid reduced iron and the char in the above example, they may be charged by the same system. In the case of classifying the solid reduced iron and the char and separately charging them into the iron-melting furnace, the auxiliary raw material and the other charged materials may be added to the char and charged together by the same system. It is more preferable to charge the char together with the auxiliary raw material and the other charged materials since the solid mass feed rate per unit time becomes larger and the scattering of the char can be more securely prevented.
Although the solid reduced iron F and the char G are charged using the container and the hopper both provided with the slide gate valve according to the illustrated batch charging method, the container may be dispensed with and the solid reduced iron F and the char G taken out from the rotary hearth furnace may be directly charged into the hopper provided with the slide gate valve and the solid reduced iron F and the char G may be intermittently dispensed by opening and closing the slide gate valve if the rotary hearth furnace and the iron-melting furnace can be installed proximate to each other.
In the above example, a reduction in the oxygen gas blowing rate at the time of charging the solid reduced iron and the char into the iron-melting furnace is accomplished by providing the iron-melting furnace with a plurality of lances and reducing or stopping the oxygen blowing rate from all or some of the lances. However, the iron-melting furnace may be provided with only one lance and the oxygen blowing rate from this lance may be reduced.
Although the baffle plate is disposed at the ceiling portion of the iron-melting furnace in the above example, guiding means 115 such as a guide plate 115′ or a guide duct 115″ may be disposed at the reduced iron charging opening 112 as shown in
Although the iron ore is used as the iron oxide source in the above example, blast furnace dust, mill oxide and the like containing iron oxide may be concomitantly used. Further, matters containing nonferrous metals and their oxides together with iron oxide such as dust and slag discharged from a metal refinery may also be used.
Although coal is used as the carbonaceous reducing agent, the bedding carbonaceous material and the additional carbonaceous material in the above example, cokes, oil cokes, charcoals, wood chips, waste plastics, old tires and the like may also be used.
Although the carbonaceous-material containing pellets are used as carbonaceous-material composite agglomerates and granulated by the granulator in the above example, carbonaceous-material containing briquettes may be used instead of the carbonaceous-material containing pellets and may be molded by compression by a compression molding machine. In this case, depending on the kind of the binder, moisture may not be added and rather dried raw material may be used at the time of molding. Since the strength of the carbonaceous-material containing briquettes can be improved to suppress the bursting at the time of heating by increasing the compressive force of the compression molding machine, even a carbonaceous material containing a volatile content of 30 mass % or higher can also be used as the carbonaceous material to be contained.
Although a combination of the charging pipe and the dispersion screw are used as the means for feeding the bedding carbonaceous material to the hearth in the above example, the bedding carbonaceous material may be dispersed on the hearth by a vibratory feeder.
Although the oxygen gas is used as the oxygen-containing gas in the above example, high-temperature air or oxygen-enriched high-temperature air may be used.
Although the rotary hearth furnace is used as the moving furnace type reducing furnace in the above example, a linear furnace may be used.
Although the carbonaceous material as the energy source for the iron-melting furnace is burnt with the oxygen-containing gas in the above example, an electric energy may be used.
Although the screen is used as the classifying means in the hot-classifying step in the above example, means for classifying the particles based on differences in travel caused by the particle size by letting them drop from a slant surface to a free space or means for classifying the particles by the fluid beds may also be used.
Test operations were conducted on conditions shown in TABLE-2 for a case where the bedding carbonaceous material was used (Inventive Examples 1, 2) and for a case where no bedding carbonaceous material was used (Comparative Example 1), using iron ire and coal having chemical compositions shown in TABLE-1 with respect to the flow diagram of the process shown in FIG. 1, and operation results written also in TABLE-2 were obtained. Here, Inventive Example 1 was an example where only the char derived from the bedding carbonaceous material is charged into the iron-melting furnace without using the additional carbonaceous material at all; Inventive Example 2 is an example where the additional carbonaceous material was charged into the iron-melting furnace in addition to the char derived from the bedding carbonaceous material; and Comparative Example 1 is an example where all the carbonaceous materials (excluding carbon contained in the solid reduced iron) to be charged into the iron-melting furnace were directly charged into the iron-melting furnace without via the rotary hearth furnace. As a reference, items of the total coal consumptions of the rotary hearth furnace and the iron-melting furnace shown in the column of the operation results of TABLE-2 are shown in TABLE-3. In this test operations, the iron ore was crushed into particles of smaller than 1 mm; and the coal had its particle size adjusted by a combination of operations of sieving and crushing and the coal particles having particle diameters of smaller than 1 mm was used as the carbonaceous reducing agent, those having particle diameters of 1 to 5 mm (average particle diameter: 2.2 mm) as the carbonaceous material and those having particle diameters of larger than 5 mm as the additional carbonaceous material in any of Inventive Examples 1, 2 and Comparative Example 1. A range of the particle diameters of the carbonaceous-material containing pellets D was set to be 6 to 20 mm, and the number of layers of the carbonaceous-material containing pellets D to be placed on the hearth was set at 0.9 layer on the average.
As shown in TABLE-2, as compared to Comparative Example 1 in which no carbonaceous material was used, the metallization degree of the solid reduced iron increased from 85% (below 90%) to 95% (above 92%) and the total coal consumptions of the rotary hearth furnace and the iron-melting furnace could be reduced by 150 kg to 187 kg per ton of the molten iron.
Although the rotary hearth furnace needs to be regularly stopped operating in order to scrape off the deposit on the outer surface of the hearth for the protection of the hearth of the rotary hearth furnace in Comparative Example 1, the formation of the deposit on the outer surface of the hearth was hardly confirmed in Inventive Examples 1, 2 and the rotary hearth furnace needed not be stopped for such a purpose.
Further, as compared to Comparative Example 1, the average volatile matter content of the carbonaceous material (char+addition carbonaceous material) to be charged into the iron-melting furnace could be reduced from 15.9 mass % (above 15 mass %) to 1.9 mass % or below 1 mass % (below 15 mass %); an apparent reduction in the temperature of the upper iron coating of the iron-melting furnace was recognized; and the effect of reducing the heat load was recognized.
First, in order to confirm the effect brought about by the reduced oxygen gas blowing rate at the time of charging the solid particles (solid reduced iron and char), a mathematical model simulating the iron-melting furnace (including neither the baffle plate nor the guiding means) having the construction shown in
(Calculation Conditions)
Although the scattering rate of the solid particles changes depending on their apparent density and particle size distribution, the apparent density of the solid particles was set to be 1.4 g/cm3 and the particle size distribution thereof was set to be one shown in
In the case of charging the solid reduced iron and the char together, the mass ratio of the solid reduced iron to the char forming the solid particles is about 90:10 to 80:20; the apparent density of the solid reduced iron is 2 to 3 g/cm3 and that of the char is about 1.0 g/cm3; and the solid particles are assumed to contain about 4 mass % of the particles having diameters of 1 mm or shorter.
(Calculation Results)
For the case of continuously charging the solid particles, a simulation calculation was conducted by successively reducing the oxygen gas blowing rate from 100% to 30% with the oxygen gas blowing rate during the normal operation set at 100%. The calculation results are shown in
Since it was difficult to confirm the influence of the batch charging by the simulation calculation, a cold model of the iron-melting furnace corresponding to the above mathematical model was fabricated and the above influence was confirmed by a model experiment.
The model experiment was carried out by variously changing the charging frequency of the solid particles and the oxygen gas blowing rate for the case of intermittently charging the solid particles based on the case of continuously charging the solid particles. The experiment results are shown in TABLE-4. As is clear from TABLE-4, it was confirmed that the scattering rate of the solid particles was reduced from 33.4% to 20.1 to 22.3% even without reducing the oxygen gas blowing rate by intermittently charging the solid particles at regular time intervals and was further reduced to 8.6 to 8.9% by reducing the oxygen gas blowing rate simultaneously with the intermittent charging.
Test operations were conducted on conditions shown in TABLE-5 for a case where the solid reduced iron and the char were intermittently charged every 5 min. (Inventive Examples 3, 4) and for a case where the solid reduced iron and the char were continuously charged (Comparative Example 2), using iron ire and coal having chemical compositions shown in TABLE-1 and using the bedding carbonaceous material in the rotary hearth furnace. In any of Inventive Examples 3, 4 and Comparative Example 2, the solid reduced iron and the char were charged together into the iron-melting furnace, but the auxiliary raw material and the additional carbonaceous material were charged by a system different from the one for the solid reduced iron and the char. Further, neither the baffle plate nor the guiding means was provided in the iron-melting furnace. The operation results are written in TABLE-5. As shown in TABLE-5, the operation conditions of the rotary hearth furnace and the secondary combustion ratio of the iron-melting furnace were the same in Inventive Examples 3, 4 and Comparative Example 2, but the operation could be carried out by only charging the char derived from the bedding carbonaceous material into the iron-melting furnace without using the additional carbonaceous material at all in Inventive Examples 3, 4, but the additional carbonaceous material needed to be charged in addition to the char in Comparative Example. As a reference, items of the total coal consumptions of the rotary hearth furnace and the iron-melting furnace shown in the columns of the operation results of TABLE-5 are shown in TABLE-6. In these test operations, the iron ore was crushed into particles of smaller than 1 mm; and the coal had its particle size adjusted by a combination of operations of sieving and crushing and the coal particles having particle diameters of smaller than 1 mm was used as the carbonaceous reducing agent, those having particle diameters of 1 to 5 mm (average particle diameter: 2.2 mm) as the carbonaceous material and those having particle diameters of larger than 5 mm as the additional carbonaceous material in any of Inventive Examples 3, 4 and Comparative Example 2. A range of the particle diameters of the carbonaceous-material containing pellets D was set to be 6 to 20 mm, and the number of layers of the carbonaceous-material containing pellets D to be placed on the hearth was set at 0.9 layer on the average.
*1The O2 blowing rate is set at 50% in the period of 30 seconds after starting charging of solid particles.
*2The O2 blowing rate is maintained at 100% at the time of charging solid particles.
As shown in TABLE-5, as compared with Comparative Example 2 employing the continuous charging method, the effect of improving a carbonaceous material yield could be confirmed in Inventive Example 4 employing the batch charging method according to which the oxygen blowing rate was not reduced at the time of charging the solid particles. In Inventive Example 3 employing the batch charging method according to which the oxygen blowing rate was reduced at the time of charging the solid particles, the carbon content contained in the dust in the exhaust gas from the iron-melting furnace was reduced from 50 kg to 13 kg per ton of the molten iron, thereby considerably improving the carbonaceous material yield. Further, as shown in TABLE-6, the total coal consumption of the rotary hearth furnace and the iron-melting furnace could be reduced by 49 kg per ton of the molten iron by making the use of the additional carbonaceous material unnecessary.
As described above, the inventive method for producing molten iron using the molten iron producing process constructed by combining the moving hearth type reducing furnace and the iron-melting furnace is characterized by comprising the following steps (1) to (4):
(1) Reducing furnace charging step of charging the bedding carbonaceous material onto the hearth of the moving hearth type reducing furnace and placing the carbonaceous-material composite agglomerates containing the powdery iron oxide source and the powdery carbonaceous reducing agent on the bedding carbonaceous material;
(2) Reduction step of moving the hearth inside the moving hearth type reducing furnace to heat and reduce the carbonaceous-material composite agglomerates to the solid reduced iron and heating and drying the carbonaceous material by distillation into char;
(3) Melting-furnace charging step of charging the solid reduced iron and the char into the iron-melting furnace while they are hot or without being substantially cooled; and
(4) Melting step of blowing the oxygen-containing gas into the iron-melting furnace to melt the solid reduced iron, thereby obtaining the molten iron.
According to this method, the hearth can be more securely protected by using the bedding carbonaceous material to avoid troubles of the peeling of the hearth, therefore the moving hearth type reducing furnace can be continuously operated for a longer period of time. Since the devolatized char has no volatile content, the damage of the refractory by the combustion of the volatile content in the iron-melting furnace can be prevented, thereby extending the life of the refractory of the iron-melting furnace. Further, the reoxidation of the solid reduced iron in the moving hearth type reducing furnace is prevented by using the bedding carbonaceous material to achieve a high metallization degree, therefore the carbonaceous material consumption in the iron-melting furnace can be considerably reduced. As a result, the carbonaceous material consumption can be further reduced while the operations of the moving hearth type reducing furnace and the iron-melting furnace can be more stabilized.
Further, according to the inventive method, a high metallization degree of 92% or above can be achieved.
According to the inventive method, at least a part of the exhaust gas from the iron-melting furnace can be used as a fuel gas for the moving hearth type reducing furnace. By doing this, the volatile content devolatized upon heating the bedding carbonaceous material in the moving hearth type reducing furnace is effectively used as the fuel for the moving hearth type reducing furnace together with at least a part of the exhaust gas from the iron-melting furnace, thereby reducing the fuel consumption of the moving hearth type reducing furnace.
Further, according to the inventive method, another carbonaceous material can be additionally charged into the iron-melting furnace in the above step (3). By doing so, the case where the carbonaceous material consumption required by the iron-melting furnace cannot be covered only by the carbon content in the solid reduced iron F and the char G can also be coped with.
Furthermore, according to the inventive method, the hot-molding step of molding the solid reduced iron and the char while they are hot may be provided between the above steps (2) and (3). By doing so, the scattering of the fine particles at the time of charging into the iron-melting furnace can be prevented and the amount of dust in the exhaust gas from the iron-melting furnace can be considerably reduced. Therefore, the iron yield and the carbon yield can be considerably improved.
Further, the inventive method may comprise the following steps (7) to (9) instead of the above step (3):
(7) Hot-classifying step of classifying the solid reduced iron and the char into coarse and fine particles while they are hot or without being substantially cooled after taking them together out of the moving hearth type reducing furnace;
(8) Coarse particle charging step of gravitationally charging the coarse particles into the iron-melting furnace; and
(9) Fine particle injection step of charging the fine particles into the iron-melting furnace by injection.
Since the fine particles are trapped in the molten iron and/or the molten slag by these steps, the scattering of the fine particles at the time of charging into the iron-melting furnace can be prevented and the amount of dust in the exhaust gas from the iron-melting furnace can be considerably reduced. Therefore, the iron yield and the carbon yield can be considerably improved.
In the step (3) of the inventive method, the solid reduced iron and the char may be charged into the iron-melting furnace from above while being hot. By doing so, the scattering rate of the fine particles of the char and the like into the exhaust gas can be reduced, therefore the carbonaceous material yield can be improved in the entire process.
The method for charging the solid reduced iron and the char into the iron-melting furnace from above while they are hot may be a method according to which the char and the solid reduced iron are discharged from the moving hearth type reducing furnace, stored in the container, conveyed to the hopper disposed above the iron-melting furnace from the container and consequently charged into the iron-melting furnace while being hot by being intermittently dispensed from the hopper or a method according to which the char and the solid reduced iron are discharged from the moving hearth type reducing furnace, stored in the hopper and consequently charged into the iron-melting furnace while being hot by being intermittently dispensed from the hopper.
Number | Date | Country | Kind |
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2004-316532 | Oct 2004 | JP | national |
2005-042716 | Feb 2005 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP05/19701 | 10/26/2005 | WO | 4/30/2007 |