KR100504365B1 - Manufacturing method of sinter ore in high combined water ore mixing - Google Patents

Abstract

The present invention provides a method for producing a sintered ore at the time of mixing the high crystalline iron ore in the production of sintered ore for blast furnace using a high crystalline water ore with a crystal water content of 3% or more as a part of the sintering raw material, the room temperature strength and productivity It is about.

The present invention provides a sintered ore manufacturing method using 3% or more of high crystallized iron ore as a raw material for sintering, wherein the size of serpentine and silica used in the sintered ore is 1-8 mm, and a low iron oxide having low oxidation degree is added Provided is a method for producing sintered ore at the time of compounding high crystal water iron ore characterized by sintering.

In addition, in the sintered ore manufacturing method using 3% or more high crystallized iron ore as the raw material for sintering, the crushed lower iron oxide is added to the high crystallized iron ore together with 0.5 to 2.0% of quicklime, When mixing and assembling while attaching the lower iron oxide to the surface of the high crystal water iron ore, the pre-treated raw material is mixed with other sintered raw materials in a drum mixer and sintered after sintering It provides a sintered ore manufacturing method.

Description

Manufacturing method of sintered ore in mixing high crystal water iron ore

The present invention relates to a sintered ore manufacturing method, in particular, in the production of sintered ore for blast furnace by using a high crystalline water iron ore having a crystal water content of 3% or more as a part of the sintered raw material, it is to improve the room temperature strength, productivity and quality recovery It relates to a method for producing sintered ore at the time of mixing the purified water ore.

In general, the quality control index of sintered ore, which is the main raw material for producing iron in blast furnace, includes strength, reducing ability, low temperature reduction differentiation, etc., and the quality index of these sintered ores is strictly managed for stable blast furnace operation.

The sintering apparatus required to produce the sintered ore is configured as shown in FIG. 1 so that in normal operation, the unit sintering bogie 1 as shown in FIG. In the lower part of the sintered trolley | bogie 1, the grate 2 is provided, and air is inhaled from the upper part to the lower part through this grate 2 ,.

Raw materials used for sintering are usually CaO-containing raw materials such as iron ore of 10 mm or less, limestone (3 mm or 5 mm or less), quicklime (1 mm or less), and small amounts of raw particles, and SiO ₂ -containing raw materials such as silica and serpentine. (1 mm or less) and solid fuels such as coke or anthracite (3 mm or 5 mm or less), and these raw materials have a compounding ratio determined in consideration of the quality and composition of the sintered ore produced. (Bin) is cut out by a certain amount, these are mixed in a drum mixer (Drum Mixer) and added to the appropriate amount of moisture, granulated,

The compounding raw materials 7 assembled as described above are quantitatively cut out by the drum feeder 8 after being charged into the hopper 6 and moved along the charging ramp plate 5 to the upper portion of the grate 2 of the sintered trolley 1. It is charged.

After the blended raw material 7 is charged into the sintered bogie 1 as described above, the ignition furnace 4 heats and charges the upper part of the charged raw material by the ignition device, and continuously sucks air from the lower part of the sintered bogie 1. When the raw materials such as coke or anthracite coal contained in the blended raw material 7 are burned, heat is generated, and iron ore reacts with the subsidiary materials to produce a melt, and the melt combines the iron ore with each other. To make a big chunk.

Since the sintered trolley 1 continuously moves along the caterpillar phase and continuously sucks air from the bottom, the combustion and melting zone of the fuel gradually moves from the top toward the lower side of the sintered trolley 1. When the melting zone reaches the grate 2 under the sintering bogie 1, the sintering is completed. After discharging the huge sintered mass from the light distribution unit, the sintering bogie 1 becomes empty and rotates to return to its original position. The same process is repeated over and over again.

The light sintered lump is crushed by a crushing device, and the sintered ore with a certain particle size is recovered as a characteristic and used as a blast furnace raw material, and the sintered ore below a certain size (usually 5 mm or less) is called a return ore. It is used as a raw material for sintering after mixing and reassembling with other raw materials.

The prepared sintered ore is composed of materials such as calcium ferrite (CaO-Fe ₂ O ₃ ), magnetite (Fe ₃ O ₄ ), hematite (Fe ₂ O ₃ ) and glassy silicate slag produced mainly by the reaction of iron ore and limestone. The relative composition ratios of the sintered ores vary greatly depending on the fuel ratio in the blended raw material (7), the chemical composition of the raw materials, the particle size of the raw materials, and the operating conditions of the sintering machine. The differentiation characteristics, reducing and cold reducing properties, vary greatly.

In the manufacture of such sintered ore, hematite (Fe ₂ O ₃ ) or a small amount of magnetite (Fe ₃ O ₄ ) has been used as an iron raw material for making sintered ore, but recently, as these high-quality iron ores are depleted, goethite ( The use of highly crystalline iron ore containing a large amount of Fe ₂ O ₃ nH ₂ O) is gradually increasing.

The high crystal water iron ore is characterized by a variety of chemical composition, depending on the acid, but usually contains more than 3% of water and SiO ₂ , 1.2 ~ 2.7% of Al ₂ O ₃ and is porous, after the crystal water is removed by heating In particular, the porosity is very high, and when used as the sintering raw material is usually 15% or more, there is a problem that the recovery rate and productivity significantly decrease with the strength of the sintered ore.

Generally, the composition ratio of raw materials to be manufactured in sintered ore depends on the characteristics of the blast furnace, but it is generally about 75 ~ 85% of iron ore, about 10 ~ 16% of limestone (CaCO ₃ ) and 1 ~ 2 of serpentine and silica, respectively. Since it is about%, the calcium ferrite formation reaction generated by the reaction between CaO and iron ore in iron ore sintering is the main reaction of the sintering reaction.

When iron ore with high crystallinity is used as a sintering raw material, moisture is blown out by pyrolysis of the sintering process, and the specific surface area of iron ore is greatly increased due to the increase of cracks and pores, thereby assimilation with limestone, serpentine and silica. Reactions also occur rapidly.

FIG. 3 is Fe in the melt due to an increase in assimilation reaction when the iron ore usage ratio of about 9% crystallization increases with the liquidus temperature change of the melt according to the Fe ₂ O ₃ concentration change in the CaO-Fe ₂ O ₃ based state diagram, which is a calcium ferrite _The concentration of ₂ O ₃ increases, indicating that the liquidus temperature of the melt increases. The liquidus temperature of the melt, which represents the melting temperature of the substance, increases the viscosity of the melt generated during sintering, thereby degrading the fluidity of the melt. It will greatly affect the quality and operation of the sintered ore.

That is, in the sintering reaction, a large amount of CO ₂ gas is generated in accordance with the pyrolysis of limestone and combustion of fuel, and not only these CO ₂ gases but also air are easily trapped in the melt, and the bubbles trapped in the melt have fluidity of the melt. Depending on the exit of the melt is well discharged or trapped in the melt, the degree of bubble trapped in the melt and the size of the bubble has a great influence on the strength, recovery and productivity of the sintered ore.

When the fluidity of the melt is good, bubbles easily escape from the melt, forming an open pore that is advantageous for the flow of air, thereby securing a passage through which the air flows, which is advantageous for sintered ore productivity. Less coarse pore residues adversely affect the strength.

However, when the fluidity of the melt is poor, bubbles are hard to escape from the melt, so that many coarse waste holes remain in the sintered ore obtained after the sintering reaction, and the strength and recovery rate of the sintered ore are also lowered due to these causes.

The reaction between hematite iron ore and limestone, which accounts for most of the sintered raw material, is primarily performed after the reaction of finely divided hematite and limestone to form a melt, and then the melt gradually diffuses from the surface of the coarse particles of hematite, gradually into the iron ore. Since the reaction proceeds, a large portion of hematite is left in the sintered ore in an unreacted state in the sintered ore generated after the sintering is completed.

Therefore, in the high temperature CaO-Fe ₂ O ₃ melt, Fe ₂ O ₃ content is relatively low, the fluidity of the melt is also good. As a result, bubbles trapped through various reactions and paths in the melt easily escape from the melt having good fluidity to the outside, and the amount of bubbles present in the melt is small, so that the productivity of the sintered ore is not only good but also obtained after cooling after sintering. In the sintered ore, as shown in FIG. 4, the size of the waste hole 14 is small and the porosity is low, so that the strength of the sintered ore is good.

However, when sintering the high-crystallized iron ore by high mixing, as the high-crystallized iron ore is heated during sintering, the crystal water dissociates and flies, and the gore ore changes to hematite 12 as shown in FIG. 15 is formed in large quantities.

Therefore, the reaction between high crystal water iron ore and CaO is different from the surface diffusion reaction as in hematite-based iron ore, and since the melt penetrates into the iron ore along the crack zone 15 in the iron ore, the melt and iron ore react rapidly and thus, hematite (12) ) A much larger amount of melt is produced than in use, and consequently, the concentration of Fe ₂ O _{3 in} the CaO-Fe ₂ O ₃ melt is relatively high.

In addition, since the SiO ₂ content is higher than that of hematite (12) in general high crystal water ore, together with the Fe ₂ O ₃ component in the iron ore The SiO ₂ component also rapidly participates in the melt generation reaction, and the concentration of SiO ₂ in the calcium ferrite melt increases.

Increasing the SiO ₂ concentration in the calcium ferrite melt greatly increases the viscosity of the melt as shown in FIG.

Thus, in the sintered melt centered on the calcium ferrite (13), Fe ₂ O ₃ and Increasing the concentration of the SiO ₂ component significantly degrades the fluidity of the melt.

As a result, in the sintered ore structure obtained after the sintering reaction, a large number of coarse waste holes 14 of about 1 to 5 mm remain as shown in FIG. 7, and the strength and recovery rate of the sintered ore are also lowered due to these causes. Various techniques have been proposed to maintain and improve the quality and productivity of the sintered ore during sintering by multiplying.

For example, the protective layer forming method selectively attaches high melting point materials, such as serpentine and converter slag, to the surface of granulated high crystal water iron ore to form a protective layer, thereby suppressing rapid reaction between iron ore and secondary raw material limestone, thereby reducing Fe in the melt. ₂ O ₃ concentration It is a method of preventing the formation of a large amount of coarse waste holes due to the deterioration of the rapid rise and the fluidity of the melt.

However, this method requires the addition of a large amount of subsidiary materials, such as serpentine or converter slag, as the proportion of high crystal iron ore increases, which increases the slag component (MgO, SiO ₂ ) in the sintered ore and uses a large amount of sintered ore. In the blast furnace, there is a problem of raising the slag ratio,

In addition, the pre-heating method is a method in which high-crystal iron iron ore is previously heated to 1300 ° C. or higher to evaporate crystal water and extinguish the generated cracks and then used as a sintering raw material, but the energy cost of processing at high temperature is high. have.

The present invention has been made to solve the above-mentioned problems of the prior art, the room temperature strength, productivity and recovery rate without the use of a large amount of high crystal iron iron ore as a raw material for sintering, without degrading the productivity of sintered ore and greatly increasing the use of secondary raw materials. It is an object of the present invention to provide a method for producing sintered ore at the time of compounding high crystal water iron ore, which can achieve maintenance and improvement of the composition.

In order to achieve the above object, in the sintered ore manufacturing method using 3% or more high-crystallized iron ore as a sintering raw material, the low particle size of serpentine and silica is 1-8 mm and low oxidation degree Provided is a method for producing a sintered ore at the time of compounding high crystal water iron ore, which is sintered by adding iron oxide.

In the present invention, the mixing ratio of the lower iron oxide is characterized in that the high crystal water iron ore is proportional to the proportion of the weight component of the sintered raw material.

In addition, according to the present invention, in the sintered ore manufacturing method using 3% or more high crystallized iron ore as the raw material for sintering, uncrushed lower iron oxide is added to the high crystallized iron ore together with 0.5 to 2.0% of quicklime, and water in a drum mixer Mixing and assembling while attaching the lower iron oxide to the surface of the high crystal water iron ore, and mixing the pretreated raw material with other sintering raw materials in a drum mixer, and sintering the mixture. A method for producing a sintered ore is provided.

In the present invention as described above, the lower iron oxide is characterized in that it is a mill scale or steelmaking sludge containing wustite and metal iron.

Hereinafter, the present invention will be described in detail.

In order to solve the above-mentioned problems in the production of sintered ores using high-crystallized iron ore having a crystalline water content of 3% or more as a raw material, the core of the present invention is characterized in that the size of serpentine and silica added during sintering It is to coarsen and add to the particle size range which is hard to fully assimilate, ie, 1-8 mm.

The reason why the size of silica or serpentine added to iron ore sintering is coarsened to 1 to 8 mm as described above is that silica or serpentine is more likely to react with FeO of lower iron oxide than Fe ₂ O ₃ in general iron ore. This is to minimize the phenomenon that SiO ₂ component, which reacts easily with limestone having a smaller particle size than iron ore, greatly deteriorates the fluidity of the sintered melt, is melted in the melt.

In addition, since the silicate melt formed by the reaction of serpentine and silica with limestone, iron ore and lower iron oxides is cooled after sintering, most of the tissues are amorphous and have weak strength and adversely affect reduction. It is to increase the particle size range to suppress the formation of these silicate materials, i.e., the amorphous structure in the sintered ore, and instead, to make a large amount of calcium ferrite 13, which is a very good strength and easily reduced in the sintered ore structure.

In addition, the present invention is to add a low oxidation oxide (Oxide materials of low oxidation degree) to the operation of the sintered ore, the lower iron oxide is mill scale or containing a ustite (FeO) and metal iron (Metal Fe) or It is distinguished by blending with other sintering raw materials as steelmaking sludge and then granulating.

At this time, the lower iron oxide is not crushed (about 1 mm particle size) for better effect, added to the high crystal iron iron ore with about 0.5-2.0% of quicklime as a binder, and then added with water in a drum mixer. The low iron oxide is attached to the surface of the high crystal water iron ore by assembling.

Thereafter, the pretreated raw materials are mixed and assembled again with the other remaining sintered raw materials in a separate drum mixer to process the raw materials, and the blended raw materials obtained through such a process are sintered by a conventional sintering apparatus.

At this time, the reason for adding the quicklime in the range of 0.5 ~ 2.0% is that the quicklime is used for the purpose of strengthening the assembly in the pretreatment of the compounding material, the price is high and effective in assembling within the 0.5 ~ 2.0% blending range Above all, it is difficult to expect a great effect.

Meanwhile, in the present invention, the compounding ratio of the lower iron oxide should be increased in proportion to the weight composition ratio of the high-crystallized iron ore having the crystal water content of 3% or more in the sintered raw material including the entire iron ore and the sub-raw material. In the range where the mixing ratio is about 15 to 50% of the total sintered raw materials (all iron ore raw materials + quartzite, serpentine and limestone) except for return ore and fuel, about 2 to 8% is suitable for mill scale. In the case of adding steelmaking slag containing metal oxide having a lower degree of oxidation, the compounding ratio may be lower than this.

The mixing ratio of the high crystal water iron ore is limited to 15 to 50% because the compounding effect is hardly exhibited at 15% or less, and when it is used at 50% or more, it is difficult in terms of technology as well as overmelting in the sintering reaction and productivity and recovery rate. This is because the sinterability improvement effect is expected in about 15 to 50% of range.

In addition, the mixing ratio of the mill scale is limited to 2 to 8% because the sinterability is greatly improved by increasing and compounding within such a mixing range.

As described above, when FeO and metal iron, which are lower iron oxides, FeO and CaO in the sintered material react in a reducing atmosphere at the beginning of the sintering reaction, thereby easily generating a CaO-FeO-based melt.

The state diagram of the CaO-FeO system is the same as in FIG. 8, but the CaO-FeO melt has a lower temperature of melting than the CaO-Fe ₂ O ₃ system of FIG. 3. As such, when the melt is formed at a relatively low temperature during sintering, the fluidity of the melt becomes relatively very good.

In this way, after the melt having good fluidity due to the addition of the lower iron oxide is primarily formed, the high crystal water iron ore penetrates into the crack zone 15 generated by pyrolysis, and thus, components such as Fe ₂ O ₃ and SiO _{2 in} the iron ore In the melt, the iron and SiO ₂ concentrations increase.

On the other hand, as is widely known, FeO component in the melt has an effect of cutting the network structure of SiO ₂ present in the melt to improve the fluidity of the melt, and thus SiO in the melt in accordance with the production of a large amount of high crystal iron ore Even if the concentration of ₂ is increased, the fluidity of the melt does not deteriorate significantly due to the effect of the SiO ₂ network cutting by FeO.

The lower iron oxide is more easily reacted with CaO in the initial reducing atmosphere when the lower iron oxide is not crushed and then attached to the high crystal iron ore rather than simply mixed and assembled with other raw materials. In addition, since most of the lower iron oxides participate in the low-melting melt formation reaction, it is more effective in the sintering of high crystal iron ore.

Thus, in the melt having good fluidity, not only CO ₂ gas generated by pyrolysis of various limestones and combustion of coke, but also the air in the crack 15 may easily escape to the outside of the melt even if trapped in the melt. Adverse effects can be minimized.

In the oxidizing atmosphere at the end of the sintering reaction, the lower iron oxide contained in the CaO-FeO system reacts with oxygen to become CaO-Fe ₂ O _{3, which} is oxidized to generate an exothermic reaction. Therefore, the temperature of the melt is increased to improve the fluidity of the melt. However, if too much is added, it is necessary to select an appropriate blending ratio because the excessive amount of heat due to the oxidative heat can worsen the sinterability.

EMBODIMENT OF THE INVENTION Hereinafter, this invention is demonstrated in detail based on an Example.

Example 1

In Example 1 of the present invention, when the high crystal water iron ore is used, the quality of the sintered ore and the improvement of operation when the coarse grain size of the serpentine rock and the silica presented in the present invention, the simple addition of the low iron oxide, or the non-crushing are attached to the high crystal water iron ore In order to test, a sintering test was conducted.

The specifications of the sintering test pot (POT) used in the test are shown in Table 1. On the other hand, Table 2 shows the blending ratios for the case where no low iron oxide mill scale was added when the high crystal water iron ore having about 9% crystal water content was included and when the mill scale was added 5%. have.

Table 1 Sintering test condition of sintering simulation tester

   Pot diameter    240 (mm)    After sintering layer    500 mm    Ignition temperature    1100 ℃    Ignition time    2 minutes    Initial Underpressure in Sintered Layer 1500 (mmH ₂ O)

Table 2 Raw Material Blend Ratio for Sintering Test (Unit:%)

   Compounding ratio 1    Compounding ratio 2    hematite        42      37    magnetite         3       3    High Crystalline Iron Ore        35      35    Mill scale         0       5    Limestone       15.1     15.1    quicklime        1.4      1.4    Serpentine        2.5      2.5    burr        One      One    sum       100      100

When the particle size of serpentine and silica was changed to 1mm and 8mm for each of these mixing ratios, the mill scale was simply blended, and the milled mill scale was pre-treated with the high crystal iron iron ore and mill scale on the surface of the high crystal iron iron ore. In accordance with the conditions of Examples 1, 2, 3, 4, and 5 of Table 3 for the case of attachment of raw materials, and after adjusting the particle size of serpentine and silica, and processing the raw materials, the raw materials assembled in the conventional method in the drum mixer are charged. It was charged to a test port with a particle size of 1.95 and subjected to a sintering test.

The sintering results obtained from these working conditions are shown in Table 4. Example 1 of Table 4 includes 35% of the high crystallized iron ore, but if no action is taken, it can be seen that the strength, recovery and productivity of the sintered ore are lower than those of all the other examples.

Table 3 Condition of sintering test

  Formulation condition High Crystalline Iron Ore Pretreatment  Serpentine granularity  Quartz grain size   Example 1   Compounding ratio 1   Not carried 1 mm 1 mm   Example 2   Compounding ratio 1   Not carried 8 mm 8 mm   Example 3   Compounding ratio 2   Not carried 1 mm 1 mm   Example 4   Compounding ratio 2   Not carried 8 mm 8 mm   Example 5   Compounding ratio 2  A fine mill scale is applied to the surface of high-crystal steel 8 mm 8 mm

Table 4 Sintering Test Results

  Example 1   Example 2   Example 3   Example 4   Example 5 Room temperature strength (%)    69    71.5    71.8    73.7    74.5 Recovery rate (%)    65    68.7    69.2    72.0    73.0 Productivity (T / D / ㎡)    29    30    31    31.5    32.5

In Example 2, it contained 35% of the high crystallized iron ore, but the grain size of serpentine and silica was coarsened to 8 mm without adding mill scale. As shown in the table, the coarsening of the serpentine and silica was improved only in the strength, recovery, and productivity of the sintered ore. This resulted in the coarsening of the serpentine and the silica to suppress the reaction with the melt generated during the sintering process. , The SiO ₂ content in the melt did not increase so much that the fluidity of the melt did not deteriorate significantly. As a result, calcium ferrite having good strength was suppressed instead of the coarse waste hole 14 and the formation of a weak amorphous silicate in the sintered ore. 13) generated a lot of strength and recovery was greatly improved, thereby improving productivity.

Examples 3 and 4 contain 35% of high-crystallized iron ore and 5% of mill scale, but the size of serpentine and silica was 1 mm and coarse to 8 mm. Even when a large amount of high crystallized iron ore is blended as in Example 3, when an appropriate amount of mill scale is added, the sinterability is improved as compared with the case where no action is taken or the grain size of serpentine and silica is coarse as in Examples 1 and 2. It can be seen that the strength, recovery and productivity of the sintered ore increased, but when the grain size of serpentine and silica was coarsened to 8 mm with mill scale addition as in Example 4, it was further improved.

Example 5 is a test result obtained by sintering mill scale crushed to 1 mm with high crystallized iron ore in a separate drum mixer and then mixing and assembling again with other sintering raw materials. Similarly, strength, recovery and productivity were all the best compared to the other examples.

Example 2

After confirming the effect of the present invention through the small sintering test model as described above, the test operation was carried out using an industrial dwight-loyid type sintering facility that produces a large amount of sintered ore. If the particle size of serpentine and silica is 1 mm without adding mill scale under the raw material blending condition containing 30% of high crystallized iron ore containing about 9% of the amount, 3% of mill scale is mixed and the particle size of serpentine and silica is adjusted. The test operation was carried out in two cases coarse to 8 mm.

As a result, mill scale was added in the state of 30% of high crystallized iron ore, and the grain size of serpentine and silica was 8 mm, and the sintered ore strength was 1 mm compared to the case where the grain size of serpentine and silica was 1 mm without adding mill scale. 1, the property recovery rate is 1.6, the productivity is improved by about 1, it was confirmed that the present invention has a great effect in maintaining the strength, recovery and productivity of the sintered ore as a method for producing a sintered ore when mixing the high crystal water iron ore.

As described above, according to the present invention, there is a useful effect of improving the strength, property recovery rate, and productivity of the sintered ore without increasing the energy cost, the slag component in the sintered ore, and the subsidiary materials.

1 is a front schematic view showing a configuration of a sintering machine

FIG. 2 is a perspective view showing a sintering cart in the sintering machine shown in FIG.

3 is a graph showing the liquidus temperature change according to the high-crystallization iron ore multiplication in the CaO-Fe ₂ O ₃ system state diagram

4 is a structure diagram of sintered ore obtained as a result of hematite sintering

5 is a texture diagram showing a crack formed in the iron ore as a result of heating the high crystal water iron ore

6 is a graph showing the viscosity change of the melt according to the SiO ₂ concentration change in the CaO-Fe ₂ O ₃ -SiO ₂ state diagram

7 is a structure diagram showing a sintered ore obtained by high mixing of high crystal water iron ore

8 is a CaO-FeO-based state diagram

<Explanation of symbols for main parts of drawing>

 1: sintering truck 4: ignition furnace

 7: Blended material 9: Upper light hopper

10: upper light 12: hematite

13: calcium ferrite 14: pores

15: cracking band

Claims (4)

In the sintered ore manufacturing method using 3% or more high-crystallized iron ore as the raw material for sintering, A method for producing sintered ore at the time of blending high crystal water iron ore, characterized in that the particle size of serpentine and silica used in the sintered ore manufacturing is set to 1 to 8 mm and low iron oxide having a low oxidation degree is added. The method for producing sintered ore according to claim 1, wherein the mixing ratio of the lower iron oxide is proportional to the weight composition ratio of the high crystal water iron ore in the sintered raw material. In the sintered ore manufacturing method using 3% or more high-crystallized iron ore as the raw material for sintering, Uncrushed lower iron oxide is added to the high crystal water iron ore with quicklime 0.5 to 2.0%, mixed and assembled with the addition of water in a drum mixer to attach the lower iron oxide to the surface of the high crystal water iron ore, and the pretreatment A method of producing a sintered ore at the time of blending high crystal water iron ore, characterized in that the raw material is mixed with other sintered raw materials in a drum mixer, and then granulated. 4. The method of claim 1 or 3, wherein the lower iron oxide is a mill scale or steelmaking sludge containing wustite and metal iron.