JPH068451B2 - Converter molten steel carbon estimation method - Google Patents

Description

The present invention relates to a method for estimating the carbon content of molten steel during converter refining using dephosphorized hot metal.

[Prior Art] A consumable measuring sensor is attached to a sublance provided in parallel with an oxygen lance to measure the solidification solid temperature T _S.
[C] is obtained from the relational expression between T _S and the amount of carbon [C] in molten steel, [C] = aT _S + b (a and b are constants) (A).

[Problems to be Solved by the Invention] However, in the above formula (A), the amount of Mn in the molten steel is 0.5 wt.
It is applied when the value is lower than%. However,
In converter refining using dephosphorized hot metal, the amount of Mn in the molten steel is high, 0.5 wt% to 1.
It is about 5 wt%. Therefore, when the above formula (A) is applied, the influence of the amount of Mn in the molten steel is not taken into consideration, and there is a problem that the accuracy of the amount of molten steel carbon obtained is insufficient.

The present invention has been made in view of such circumstances, and an object thereof is to provide a highly accurate converter molten steel carbon estimation method in consideration of the amount of Mn in molten steel.

[Means for Solving the Problem] A converter molten steel carbon estimation method according to the present invention is a method for estimating the carbon content of molten steel during converter smelting using dephosphorized hot metal. Measuring its temperature and solidification temperature, (2) obtaining a primary estimated carbon amount in the molten steel from the solidification temperature, (3) using the primary estimated carbon amount and the molten steel temperature,
A Mn equilibrium equation in the converter and obtaining an estimated Mn amount in molten steel from a mass balance equation; (4) obtaining a carbon amount using the solidification temperature and the estimated Mn amount. And

[Operation] According to the present method, although it is an estimated value of Mn, it is considered as one factor for estimating the carbon amount, so that the carbon amount can be estimated more accurately than the conventional method. .

[Example] A consumable measuring sensor was attached to a sublance provided in parallel with an oxygen lance, and the temperature T of the molten steel and the solidification temperature T were set.
Measure _S. The primary estimated carbon amount [C] ₁ is obtained from the relational expression between T _S and the carbon amount [C] in molten steel, [C] = aT _S + b (a and b are constants) (1).

On the other hand, the Mn balance equation and the Mn mass balance equation are expressed by the following equations (2) and (3), respectively.

log {(Mn) / [Mn]} ＝ log (A / [C]) ＋ B / T ＋ C …… (2) W _M [Mn] ＋ W _S (Mn) ＝ W _P [Mn] _P ＋ δM _O …… (3 ) where, T is the molten steel temperature, [Mn], (Mn) , [Mn] P respectively molten steel, slag, M _n in the hot metal
Amounts, W _M , W _S , W _P , and W _O are the weights of molten steel, slag, hot metal, and M _n ore, δ is the amount of M _{n in} M _n ore, and A, B and C are constants.

The nonlinear equation for [Mn] obtained by eliminating (Mn) from Eqs. (2) and (3) is solved by the numerical method with [C] = [C] ₁ . The estimated Mn amount obtained here is written as [Mn] ₁ .

The above [Mn] _P , W _M , W _P , W _O are measured during normal operation and are actually measured values. W _S is calculated from the amount of auxiliary raw material input during refining and the slag component of the precharge.

The amount of carbon [C] in the molten steel is expressed as [C] = DT _S + E [Mn] + F (4) as a linear expression of T _S and [Mn] with practical accuracy.

Here, D, E, and F are constants obtained in advance by multiple regression analysis from the analytical values of the collected molten steel samples.

The constants D, E, F obtained here and the above [Mn] ₁ are put into the above equation (4) to determine the carbon content [C] in the molten steel.

Thus, the carbon amount [C] in the molten steel can be obtained with high accuracy in consideration of [Mn].

Next, specific numerical values according to this embodiment will be described.

The constants included in the nonlinear equation for [Mn] obtained from the above equations (2) and (3) include [Mn] _P = 0.16%, W _M = 310T, W _S = 3T, W _P = 300T, W _O = 6.3T, δ = 0.55, A = -0.170, B = 15.08, C = 10867.9 was used to obtain [Mn], and [Mn] = 1.34% was obtained. Also,
The values obtained by multiple regression analysis of the constants, D, E, and F in the equation (4) are D = 0.011516, E = -0.0528, and F = 17.69. Using this value, [C] = 0.147 was obtained from equation (4). For comparison, the value of the same sample analyzed by an optical emission spectrometer is
[C] = 0.145.

Next, a comparison between the present embodiment and the conventional example regarding a large number of analysis values and estimated values will be described. FIG. 1 is a graph showing the relationship between the two, with the horizontal axis representing the estimated carbon content according to this example and the vertical axis representing the carbon content determined by the emission spectroscopy. For comparison, FIG. 2 shows the same graph as in FIG. 1 for the conventional example. According to FIGS. 1 and 2, the average x of the difference between the analysis value and the estimated value and the deviation σ are 0.001% and 0.008% in the present embodiment, respectively, and 0.011% and 0.0 in the conventional example.
It is 25%, and the accuracy of the molten steel carbon amount obtained in this example is remarkably improved as compared with the conventional example.

EFFECTS OF THE INVENTION According to the present invention, the amount of carbon in molten steel is obtained in consideration of the amount of Mn in molten steel obtained from the equilibrium formula of Mn in the converter and the equation of mass balance. improves.

[Brief description of drawings]

FIG. 1 is a graph diagram comparing the estimated carbon amount in the molten steel according to the present example with the analysis value, and FIG. 2 is a graph diagram comparing the estimated carbon amount in the molten steel according to the conventional example with the analysis value.

Claims (1)

[Claims] 1. A method for estimating the carbon content of molten steel during converter refining using dephosphorized hot metal, comprising: (1) collecting molten steel and measuring its temperature and solidification temperature; (2) the solidification Obtaining the primary estimated carbon amount in the molten steel from the temperature, (3) using the primary estimated carbon amount and the molten steel temperature,
Calculating the estimated Mn amount in the molten steel from the equilibrium equation of Mn in the converter and the equation of mass balance; (4) determining the carbon amount using the primary estimated carbon amount and the estimated Mn amount. Converter molten steel carbon estimation method.