METHOD FOR PRODUCING CHROMIUM-CONTAINING MOLTEN STEEL

Abstract

A method for producing chromium-containing molten steel from a raw material including a chromium-containing raw material includes a first step in which a slag basicity before rough decarburization by oxygen blowing is adjusted to be not less than 1.5 and not more than 3.0, a slag basicity after rough decarburization by oxygen blowing is adjusted to be not less than 2.0 and not more than 3.5, and then tapping is performed while slag containing a chromium oxide generated by the oxygen blowing is made to remain in the furnace, and a second step in which the slag containing a chromium oxide made to remain is reduced by using a carbon source or a metal source newly added into the same furnace so that chromium is recovered into molten steel. The slag basicity is determined by dividing a CaO concentration by an SiO.sub.2 concentration on a mass basis in the slag.

Claims

1. A method for producing chromium-containing molten steel comprising, using a steelmaking refining furnace, melting and heating a raw material containing a chromium-containing raw material and performing rough decarburization by oxygen blowing, wherein the method has: a first step of adjusting slag basicity before the rough decarburization by oxygen blowing in a range of not less than 1.5 and not more than 3.0 and the slag basicity after the rough decarburization by oxygen blowing in a range of not less than 2.0 and not more than 3.5 and then performing tapping while keeping the slag containing chromium oxide generated by the oxygen blowing remaining in the furnace; and a second step of reducing the remaining slag containing chromium oxide by a carbon source or a metal source newly added into the same furnace to recover chromium into molten steel, wherein the slag basicity is determined by dividing a CaO concentration by an SiO.sub.2 concentration on a mass basis in the slag.

2. The method for producing chromium-containing molten steel according to claim 1, wherein a CaO-containing raw material is added and melted during the oxygen blowing in the first step.

3. The method for producing chromium-containing molten steel according to claim 1, wherein a slag basicity (C/S)pre before the rough decarburization by the oxygen blowing and a slag basicity (C/S)post after the rough decarburization by the oxygen blowing in the first step satisfy a formula (1) below.
(C/S)post−(C/S)pre≥−0.2  (1)

4. The method for producing chromium-containing molten steel according to claim 1, wherein in the first step, after the oxygen blowing, a concentration of the oxide of chromium in the slag is set to be in a range of not less than 5 mass % and not more than 50 mass % by using one or two types selected from an Si-containing raw material and an Al-containing raw material.

5. The method for producing chromium-containing molten steel according to claim 2, wherein a slag basicity (C/S)pre before the rough decarburization by the oxygen blowing and a slag basicity (C/S)post after the rough decarburization by the oxygen blowing in the first step satisfy a formula (1) below.
(C/S)post−(C/S)pre≥−0.2  (1)

6. The method for producing chromium-containing molten steel according to claim 2, wherein in the first step, after the oxygen blowing, a concentration of the oxide of chromium in the slag is set to be in a range of not less than 5 mass % and not more than 50 mass % by using one or two types selected from an Si-containing raw material and an Al-containing raw material.

7. The method for producing chromium-containing molten steel according to claim 3, wherein in the first step, after the oxygen blowing, a concentration of the oxide of chromium in the slag is set to be in a range of not less than 5 mass % and not more than 50 mass % by using one or two types selected from an Si-containing raw material and an Al-containing raw material.

8. The method for producing chromium-containing molten steel according to claim 5, wherein in the first step, after the oxygen blowing, a concentration of the oxide of chromium in the slag is set to be in a range of not less than 5 mass % and not more than 50 mass % by using one or two types selected from an Si-containing raw material and an Al-containing raw material.

Description

BRIEF DESCRIPTION OF DRAWINGS

[0022] FIG. 1 is a flowchart showing a basic configuration of a method for producing chromium-containing molten steel according to an embodiment of the present invention.

[0023] FIG. 2 is a graph showing a relationship between a slag basicity and a liquid phase ratio generated at 1700° C. with respect to different values of chromium oxide concentration in the slag, which is calculated by using thermodynamic calculation software.

DESCRIPTION OF EMBODIMENT

[0024] A description is given of an approach taken to reach the findings of the present invention.

[0025] Chromium oxide has a melting point as extremely high as 2300° C. Slag containing chromium oxide obtained after a supply of oxygen to chromium-containing molten metal is at about 1700° C. and is high in content of chromium oxide, thus having a low liquid phase ratio and extremely high viscosity. Accordingly, in a case where only molten steel is tapped without reducing the slag containing chromium oxide, the slag remains in a large amount as adherent slag in the vicinity of the furnace wall, furnace throat, or tap hole, resulting in impairing operations.

[0026] For example, in a furnace with a relatively large capacity, such as a converter or an AOD furnace, the furnace throat tends to be increasingly narrowed. Because of this, the linear flow velocity of exhaust gas discharged through the furnace throat is increased to increase the generation amount of chromium-containing dust. As a result, the amount of Cr discharged to the outside of the system is increased.

[0027] To address this issue, with attention focused on the fact that a relationship between the liquid phase ratio of slag containing chromium oxide and slag basicity largely varies depending on the concentration of chromium oxide (Cr.sub.2O.sub.3), the inventors have discovered a method for keeping slag containing chromium oxide remaining in a furnace without affecting operations. The inventors have further found a method for producing chromium-containing molten steel at reduced costs and with a reduced generation amount of slag, by reducing the slag in the same refining furnace using a carbon source or a metal source newly added thereto.

[0028] In particular, we found that slag with a high chromium oxide concentration has a high liquid phase ratio at a high basicity, while slag with a low chromium oxide concentration has a high liquid phase ratio at a low basicity. For example, at the prime stage of decarburization after the end of the heating step, the chromium oxide concentration in the slag is not high, and thus the liquid phase ratio of the slag increases as the slag basicity decreases, resulting in a reduction in the adhesion of the slag to the furnace wall. On the other hand, at the final stage of oxygen blowing in which an increased amount of chromium oxide is generated, increasing the slag basicity rather increases the liquid phase ratio of the slag, resulting in a reduction in the adhesion of the slag to the furnace wall. In an ordinary oxygen blowing step, Si in a main raw material used or an auxiliary raw material used is combusted, and thus the slag basicity decreases toward the latter half of blowing, so that compositions of the slag before and after oxygen-blowing decarburization both need to be designed.

[0029] Here, the heating step may be performed by adding a carbonaceous material and blowing oxygen. In such a case, the duration until a temperature T(K) during the oxygen blowing is increased to a value higher than a temperature value expressed by an equilibrium formula (2) shown below can be regarded as the heating-up step. Here, a.sub.Cr represents an activity of Cr in molten metal, ac represents an activity of C in the molten metal, and P.sub.Co represents an atmospheric partial pressure (atm) of CO.

[00001]$\left[\mathrm{Mathematical}\mathrm{Formula}1\right]$$\begin{array}{cc}T=\frac{13520}{8.48-\log \left(\frac{a_{\mathrm{Cr}}^{2/3}.Math.P_{\mathrm{CO}}}{a_C}\right)}& \left(2\right)\end{array}$

[0030] FIG. 1 is a flowchart showing a basic configuration of a method for producing chromium-containing molten steel according to an embodiment of the present invention. As the first step, a raw material including a chromium-containing raw material is melted by use of a steelmaking refining furnace (S0). Subsequently, heating is performed by using electric energy, adding a heat source, or the like (S1). Further, the slag basicity is adjusted to be in the range of not less than 1.5 and not more than 3.0, and rough decarburization by oxygen blowing is performed (S2). After that, the slag basicity is adjusted to be in the range of not less than 2.0 and not more than 3.5, and then tapping is performed while keeping slag containing chromium oxide generated by the oxygen blowing remaining in the furnace (S3). Here, the slag basicity is determined by dividing a CaO concentration by an SiO.sub.2 concentration on a mass basis in the slag. The heating is carried out, for example, by energization heating, an addition of a carbonaceous material or a silicon-containing substance and oxygen blowing, or the like.

[0031] Next, as the second step, the slag containing chromium oxide made to remain in the furnace is reduced by using a carbon source or a metal source newly added into the same furnace so that chromium is recovered into molten steel (S4), and thus chromium-containing molten steel can be effectively produced.

[0032] In the first step, in order to adjust the slag basicity to be in an appropriate range in accordance with the variation in the concentration of the chromium oxide in the slag during the oxygen blowing, a CaO-containing raw material may be added and melted during the oxygen blowing. Moreover, preferably, the CaO-containing raw material is added and melted, so that a slag basicity (C/S)pre before the rough decarburization by the oxygen blowing and a slag basicity (C/S)post after the rough decarburization by the oxygen blowing satisfy a formula (1) below. This makes it possible to stably produce chromium-containing molten steel.

(C/S)post−(C/S)pre≥−0.2  (1)

[0033] The CaO-containing raw material may be added and melted by newly adding the CaO-containing raw material during the oxygen blowing or by initially adding a CaO-containing raw material in the form of an agglomerate so as to be melted during the oxygen blowing. The melting rate of the raw material varies depending on the property of the raw material, the shape of a furnace, and the agitation status, and while there have been reported various estimated formulae to this end, the melting rate may be empirically estimated from an actual variation in basicity.

[0034] In the first step, weak reduction (S5) is carried out in which the chromium oxide concentration in the slag is adjusted to be in the range of not less than 5 mass % and not more than 50 mass % by using one or two types selected from an Si-containing raw material and an Al-containing raw material, and thus it is possible to more stably produce chromium-containing molten steel.

[0035] The following describes details of the present invention.

[0036] Prior to making the invention, the inventors conducted a thermodynamic study on an equilibrium phase of slag varying in chromium oxide concentration. FIG. 2 shows a graph of an influence of a chromium oxide concentration on a relationship between the slag basicity and liquid phase ratio generated at 1700° C., which is calculated by using the thermodynamic calculation software “Factsage.” Here, the MgO concentration and the Al.sub.2O.sub.3 concentration in the slag are set to 10 mass % and 10 mass %, respectively. These values of the MgO concentration and the Al.sub.2O.sub.3 concentration represent a slag composition in a typical refining furnace, and whether these concentrations are high or low has no significant influence on calculation results.

[0037] When the chromium concentration is low, i.e., for example, the Cr.sub.2O.sub.3 concentration in the slag is 5 mass % as shown in FIG. 2, a high liquid phase ratio can be retained at the slag basicity of a relatively low range of 1.0 to 3.0. Further, the liquid phase ratio decreases with an increase in basicity. From a viewpoint of promoting the reduction of chromium oxide, preferably, the slag basicity is retained at not less than 1.5, and preferably, the basicity during rough decarburization performed by starting oxygen blowing is set to be in the range of 1.5 to 3.0.

[0038] On the other hand, we found that, when the chromium concentration is high, i.e., for example, the chromium oxide concentration in the slag is 40 mass % as shown in FIG. 2, the liquid phase ratio increases as the slag basicity increases in the range of not less than 2.0. A liquid phase generated at the basicity in the range of less than 2.0 has extremely high viscosity with the basicity of about 1.2 and therefore might adhere to a furnace wall. The basicity in the liquid phase is determined by dividing a CaO concentration by an SiO.sub.2 concentration on a mass basis in the liquid phase. In a low chromium concentration region, the liquid phase ratio is relatively high, and thus even when a liquid phase having high viscosity is generated, no operational problem is caused. When, however, a high chromium concentration region is established in the latter half of blowing, and thus a solid fraction of the slag is increasing, a pronounced influence of the viscosity is exerted on operations. In a case where the slag basicity is more than 3.5, hexavalent chromium is generated in the slag. From a viewpoint of addressing environmental problems, it is required that the slag basicity be set to not more than 3.5. Hence, preferably, the slag basicity at the end of oxygen blowing is set to be in the range of not less than 2.0 and not more than 3.5.

[0039] As described above, the basicity that allows the liquid phase ratio to reach maximum varies during the oxygen blowing in accordance with the variation of the concentration of chromium oxide during oxygen blowing. For this reason, it is preferable to intentionally add and melt a CaO-containing raw material during the oxygen blowing, so that the slag basicity (C/S)pre before rough decarburization by the oxygen blowing and the slag basicity (C/S)post after the rough decarburization by the oxygen blowing satisfy the formula (1) below. Note that the upper limit of the following formula (1) is 2.0.

(C/S)post−(C/S)pre≥−0.2  (1)

[0040] When the chromium oxide concentration is about 60 mass %, the basicity of the liquid phase portion hardly increases even at increased slag basicity. Thus, the chromium oxide concentration in slag is preferably set to not more than 50 mass %. When the chromium oxide concentration in slag is less than 5%, there might be a greater disadvantage of an increase in volume of the slag than an advantage that chromium can be recovered by using the carbon source or a metal source newly charged, and thus, it is preferable to set the chromium oxide concentration in slag to not less than 5%. After the oxygen supply is stopped, an Si-containing raw material or Al-containing raw material is added in a proper amount, so that the chromium oxide concentration can be adjusted to be in this range. In this case, while, with the Si-containing raw material added, the slag basicity varies between after oxygen blowing and after weak reduction, preferably, the slag basicity after the oxygen blowing and the slag basicity after the weak reduction are both set to be in the range of not less than 2.0 and not more than 3.5.

[0041] The slag basicity before the start of rough decarburization by oxygen blowing, the slag basicity after the end of the oxygen blowing, and the slag basicity after weak reduction each can be controlled by designing the weight and timing of an addition of an auxiliary raw material to be charged during blowing.

[0042] When slag containing chromium oxide is made to remain in the furnace, chromium can be reduced and recovered by adding a carbon source or a metal source to the slag containing chromium oxide. Examples of the carbon source include hot metal, high-carbon ferrochrome, and carbonaceous material, which are separately prepared. Examples of the metal source include ferrosilicon, aluminum pellets, and aluminum dross. Since the reduction reaction of chromium oxide with carbon is an endothermic reaction, heating may be performed by energization heating or by supplying oxygen for heat supply. In the subsequent step, with the slag composition adjusted again, tapping may be performed while keeping the slag containing chromium oxide remaining in the furnace or performed after adding a metal reducing agent and then removing the slag.

EXAMPLES

Example 1

[0043] Hot metal was charged in a 150-ton converter and ferrochromium was added thereto, and then decarburization blowing was carried out to perform heating and decarburization, followed by tapping. Hot metal was charged again in the furnace after the tapping, slag containing chromium oxide was reduced so as to recover chromium, while heating by oxygen-blowing decarburization was carried out. Table 1 shows experimental conditions.

TABLE-US-00001 TABLE 1 Slag Composition [mass %] Slag Composition [mass %] After Oxygen-blowing After End of Heating Decarburization No. Cr.sub.2O.sub.3 CaO SiO.sub.2 Al.sub.2O.sub.3 C/S* Cr.sub.2O.sub.3 CaO SiO.sub.2 Al.sub.2O.sub.3 C/S* 1 10 40 10 13 4.00 53 20 4 5 5.00 2 5 37 23 14 1.61 53 16 11 7 1.45 3 7 30 22 13 1.36 54 20 10 8 2.00 4 9 38 13 20 2.92 55 25 5 8 5.00 5 5 43 17 10 2.53 53 21 9 5 2.33 6 9 42 15 10 2.80 55 20 8 5 2.50 7 10 40 18 14 2.22 57 24 8 7 3.00 8 7 40 14 14 2.86 53 23 7 7 3.29 Reduction Slag Composition [mass %] Tapping Before Before Tapping Temperature No. Tapping Cr.sub.2O.sub.3 CaO SiO.sub.2 Al.sub.2O.sub.3 C/S* [° C.] Remarks 1 Strong 1 44 20 10 2.20 1700 Comparative Reduction Example 2 Not 53 16 11 7 1.45 1700 Comparative performed Example 3 Not 54 20 10 8 2.00 1700 Comparative performed Example 4 Not 55 14 11 8 1.27 1700 Comparative performed Example 5 Not 53 21 9 5 2.33 1700 Invention performed Example 6 Weak 38 21 12 7 1.75 1700 Invention Reduction Example 7 Not 57 21 9 7 2.33 1700 Invention performed Example 8 Weak 44 24 11 9 2.18 1700 Invention Reduction Example *Slag basicity; representing (CaO concentration)/(SiO.sub.2 concentration) on mass basis

[0044] Next, the status of a furnace throat was checked with respect to the experimental conditions shown in Table 1 for the evaluation of an influence on operations. Table 2 shows results thereof. Here, the evaluation of operational stability is conducted by evaluating the reduction rate in area of the furnace throat from photographs of the furnace throat as a degree of clogging of the furnace throat. A case where an amount of reduction in the area of the furnace throat after the process was not less than 1% of the area of the furnace throat before the process was evaluated as “poor,” a case where the amount was less than 1% was evaluated as “good,” and a case where there was observed no reduction in the area of the furnace throat was evaluated as “excellent.” The used amount of the reducing agent is evaluated as “poor” when the used amount of the metal reducing agent, namely, the used amount of ferrosilicon and aluminum pellets was equal to a conventional one, and as “good” when the amount was smaller than a conventional one. Moreover, the percentage of chromium that could be recovered in the second step was evaluated as a recovery rate of chromium. Here, the recovery rate of chromium was calculated, on a mass basis, by (chromium concentration (%) in molten metal x tapping amount (t)/100−amount (t) of chromium added)/amount (t) of chromium remaining in the furnace. The recovery rate of chromium of less than 0.3 was evaluated as “poor,” and the recovery rate of chromium of not less than 0.3 was evaluated as “good.” As a comprehensive evaluation, a condition under which any of the operational stability, the used amount of a reducing agent, and the recovery rate of chromium was evaluated as “poor” was evaluated as “poor,” while among conditions under which no evaluation was made as “poor,” a condition under which the operational stability was evaluated as “excellent” was evaluated as “excellent,” and any other condition was evaluated as “good.”

TABLE-US-00002 TABLE 2 Evaluation Evaluation of Used of Opera- Amount of Recovery tional Reducing Rate of Comprehensive No. Stability Agent Chromium Evaluation Remarks 1 Excellent Poor Poor Poor Comparative Example 2 Poor Good Poor Poor Comparative Example 3 Poor Good Poor Poor Comparative Example 4 Poor Good Poor Poor Comparative Example 5 Good Good Good Good Invention Example 6 Excellent Good Good Excellent Invention Example 7 Good Good Good Good Invention Example 8 Excellent Good Good Excellent Invention Example

[0045] Under all process conditions Nos. 5 to 8 representing invention examples, it was possible to reduce and recover chromium and to decrease the used amount of the reducing agent. Moreover, under the process conditions Nos. 6 and 8 in which the chromium oxide concentration in the slag was adjusted to not less than 5 mass % and not more than 50 mass %, the rate of narrowing of the furnace throat was relatively reduced.

[0046] The foregoing examples have shown an example of stably producing chromium-containing molten steel at reduced costs and without affecting operations, and in the chromium-containing molten steel tapped according to the present invention, the oxygen concentration in the molten steel is high, and thus nitrogen absorption is unlikely to occur, so that the method is useful also as a method for obtaining high-purity molten steel. While the molten steel tapped by this method has a high oxygen concentration in the molten steel and thus is tapped in a state of having a relatively high sulfur concentration, a desulfurization process can be performed with no problem by performing a reduction process in a later step. In addition, there is no need to reduce an oxide in slag, and thus a use amount of an alloy reducing agent such as an Si-containing raw material or an Al-containing raw material can be significantly reduced. It is also useful to produce molten steel having a predetermined component concentration by combining molten steel tapped by this method and molten steel produced in a different refining vessel.

INDUSTRIAL APPLICABILITY

[0047] The method for producing chromium-containing molten steel according to the present invention is industrially useful in that it is capable of reducing a cost and an amount of generated slag and thus of reducing an environmental burden.