RU2102498C1 - Method of ladle treatment of high-carbon steel - Google Patents

Abstract

FIELD: metallurgy. SUBSTANCE: aluminum is introduced into melt before introduction of silicocalcium which consumption is preset with consideration of the calcium assimilation degree depending on assimilated aluminum and content of sulfur in melt. Lower limit of calcium content is determined by expression [Ca]=0.01[A]=0.0016%. Upper limit of calcium content in melt with sulfur content in melt equals to 0.014% is determined by expression [Ca]= 0.036[A]+0.0026%. If sulfur content in metal exceeds 0.014%, the upper limit of calcium content is determined by expression [Ca]=0.0037% - 0.042[S], where [Ca] is content of calcium dissolved in metal, %; [Al] is content of aluminum dissolved in metal, %: [S] is content of sulfur dissolved in metal, %. EFFECT: higher efficiency.

Description

 The invention relates to ferrous metallurgy, and in particular, to a method for out-of-furnace treatment of high carbon steel.

 A known method of producing high-quality steel, according to which the metal is refined in the ladle by slag, and deoxidation is carried out first with silicocalcium and then with aluminum (SU, auth. Certificate. N 447434, class C 21 C 5/04, 7/06, 1975). This method is selected as a prototype.

The disadvantage of this method is that when processing steel with silicocalcium and aluminum, the sulfur content in the metal is not taken into account. Therefore, at certain ratios of calcium, aluminum, and sulfur, solid non-metallic inclusions in the form of Al ₂ O ₃ and CaS can form in the melt, which, on the one hand, worsen the spillability of steel, and on the other hand, are stress concentrators that contribute to the development of fatigue defects, especially in highly loaded ones details.

 The basis of the invention is the task to improve the method of out-of-furnace treatment of high-carbon steel with aluminum and calcium so that it is possible to globularize sulfide inclusions and transfer solid alumina to a liquid state at a casting temperature of calcium aluminates. Such processing would enhance the casting and mechanical properties of steel. This problem is solved by establishing a certain sequence of introducing aluminum and calcium into the melt, as well as establishing the optimal ratio between the amount of introduced calcium, the amount of aluminum and the sulfur content in the metal.

The essence of the invention lies in the fact that in the method of out-of-furnace treatment of high-carbon steel, which includes introducing aluminum and silicocalcium into the melt, aluminum is introduced into the melt before introducing silicocalcium, and the silicocalcium flow rate is set taking into account the degree of calcium absorption depending on the acquired aluminum and the sulfur content in the melt. The lower limit of the calcium content in the melt is determined by the expression [Ca] ≥ 0.01 [Al] + 0.0016, and the upper limit is determined by the sulfur content in the melt up to 0.014% by the expression [Ca] ≤ 0.036 [Al] + 0 , 0026, or [Ca] ≤ 0.0037% 0.042 [S] when the sulfur content in the metal is more than 0.014% where [Ca] is the content of calcium dissolved in the metal, [Al] is the content of aluminum dissolved in the metal, [S] is the sulfur content dissolved in metal
Silicocalcium is preferably introduced into the bucket in the form of a cored wire. This method of introducing silicocalcium into the metal provides the ability to finely control the amount of calcium introduced, depending on the content of aluminum and sulfur in the metal.

 An essential feature of the invention common with the prototype is the introduction of aluminum and silicocalcium into the melt.

Distinctive features of the prototype of the essential features of the invention are: the introduction of aluminum into the melt before entering silicocalcium; the consumption of silicocalcium is established taking into account the degree of assimilation of calcium, depending on the assimilated aluminum and the sulfur content in the melt. The lower limit of the calcium content in the melt is determined by the expression [Ca] ≥ 0.01 [Al] + 0.0016, and the upper limit is determined by the sulfur content in the melt up to 0.014% by the expression [Ca] ≤ 0.036 [Al] + 0 , 0026, or [Ca] ≤ 0.0037% - 0.042n [S] when the sulfur content in the melt is more than 0.014%
An additional feature is the introduction of silicocalcium into the melt in the form of a cored wire.

 Between the essential features of the invention and the technical result - an increase in the casting and mechanical properties of steel, there is a causal relationship, which is illustrated by the following.

As studies have shown, introducing silicocalcium into steel pre-deoxidized by aluminum turns alumina into calcium aluminates, which remain liquid at casting temperatures of steel. Moreover, the calcium content in the system CaO Al ₂ About must be in certain proportions. Both deficiency and excess calcium can inhibit the formation of liquid calcium aluminates. At the same time, studies have shown that with a sulfur content in the metal of up to 0.014%, a certain ratio between dissolved calcium and aluminum must be maintained, and with a sulfur content in the metal of more than 0.014%, a certain ratio between dissolved calcium and the sulfur content in the melt must be ensured.

 Thus, to ensure the required casting and mechanical properties of steel, it is necessary to introduce a strictly defined amount of calcium into the melt, which is achieved by fulfilling the above ratios.

 Example. Steel U8 smelted in an oxygen converter was deoxidized in a ladle with aluminum in an amount of 0.3 kg per ton of steel. In the final sample, the sulfur and aluminum content in the steel was 0.010% and 0.010%. Then, SK-30 silicocalcium was introduced into the ladle in the form of a flux-cored wire. The permissible amount of introduced silicocalcium was determined as follows.

The minimum allowable amount of absorbed calcium was determined in accordance with the dependence
[Ca] ≥ 0.01 [Al] + 0.0016%
[Ca] ≤ 0.01 0.01 + 0.0016 0.0017%
The minimum allowable amount of SK-30 silicocalcium administered with an assimilation coefficient of 0.16 is
0.0017 / (0.16 • 0.30) 0.035% or 0.35 kg / t
In accordance with the dependence [Ca] ≤ 0.036 [Al] + 0.0026%, the maximum permissible amount of assimilated calcium was determined
[Ca] ≤ 0.036 • 0.01 + 0.0026 0.0032%
The amount of silicocalcium SK-30 with an assimilation coefficient of 0.16 is
0.0032 / (0.16 • 0.30) 0.066% or 0.66 kg / t.

0.55 kg / t SK-30 silicocalcium in the form of flux-cored wire was introduced into the bucket. The residual calcium content in the metal was 0.0025%. The temperature of the metal in the tundish was 1537 ^° C. At a casting speed of 0.6 m / min, the ladle metal was completely poured into a round billet without loss and tightening of the glasses. The quality of metal products according to surface defects, non-metallic inclusions met the requirements of regulatory documentation with increased impact toughness on samples with a sharp notch (CS) of 3.0-3.2 kgm / mm ² .

Example 2. Steel U8 smelted in an oxygen converter was deoxidized in a ladle with aluminum in an amount of 0.37 kg / t. In the final sample, the steel had a sulfur and aluminum content of 0.025% and 0.020%, respectively. The metal temperature was 1570 ^° C. Then SK-30 silicocalcium was introduced into the ladle in the form of a cored wire.

 The permissible amounts of introduced silicocalcium were determined as follows.

The minimum allowable amount of absorbed calcium was determined by the dependence
[Ca] ≥> 0.01 [Al] + 0.0016%
[Ca] ≥ 0.01 • 0.020 + 0.0016 0.0018%
The minimum allowable amount of SK-30 silicocalcium administered with an assimilation coefficient of 0.16 is
0.0018 / (0.16 • 0.30) 0.039% or 0.39 kg / t.

In accordance with the dependence [Ca] ≤ 0.0037% 0.042 [S] the maximum allowable amount of absorbed calcium was determined
[Ca] ≤ 0.0037 0.042 [S] 0.025 0.0027%
The amount of silicocalcium SK-30 with an assimilation coefficient of 0.16 is
0.0027 / (0.16 • 0.30) 0.056% or 0.56 kg / t.

0.4 kg / t silicocalcium was introduced into the bucket in the form of cored wire. The residual calcium content in the metal was 0.0020%. The temperature of the metal in the tundish was 1540 ^° C. At a casting speed of 0.6 m / min, the metal was completely cast. The quality of metal in non-metallic inclusions is satisfactory. Metal products had a homogeneous structure, high plastic characteristics and impact strength on specimens with a sharp notch of 2.9-3.1 kgm / mm ² .

Claims (1)

 A method for the out-of-furnace treatment of high-carbon steel, comprising introducing aluminum and silicocalcium into the melt, characterized in that the aluminum is introduced into the melt before the silicocalcium is introduced, and the silicocalcium consumption is set taking into account the degree of calcium absorption depending on the absorbed aluminum and the sulfur content in the melt, while the lower limit the calcium content in the melt is determined by the expression [Ca] 0.01 [Al] + 0.0016% and the upper limit is determined when the sulfur content in the melt is up to 0.014% by the expression [Ca] 0.036 [Al] + 0.0026% or [Ca ] 0.0037% 0.042 [S] with sulfur content s in the metal is more than 0.014% where [Ca] is the content of calcium dissolved in the metal, [Al] is the content of aluminum dissolved in the metal, [S] is the content of sulfur dissolved in the metal,