RU2476278C2 - Method of producing hot-rolled wide-strip steel - Google Patents

Abstract

FIELD: process engineering.

SUBSTANCE: proposed method comprises hot rolling, accelerated strip cooling at preset temperatures, and coiling. Rolled stock strength is increased in rolling steel sheet of ferrite-martensitic steel structure containing 0.09…0.11 wt % of carbon, 0.37…0.65 wt % of silicon, 1.25…1.60 wt % of manganese, 0.48…0.57 wt % of chromium, and 0.02…0.1 wt % of nickel at relationship between yield point and ultimate strength of ≤ 0.8 c σ_m=450…1000 N/mm². Note here that between preliminary and final cooling, rolled stock is held in air. Note also that metal temperature in final pass exceeds temperature of Ar₃ by 0…25°C, while temperature after preliminary accelerated cooling is kept lower than that of Ar₁ by Δ_ac=-0.0005 σ_m ² +0.99 σ_m-342.84. Note that coiling temperature is kept lower than Ar₁, by Δ_coil=-0.0013 σ_m ²+2.33 σ_m-496.5. Note that magnitudes of Ar₃ and Ar₁ are calculated by formulae: Ar₃=879.2-94.24 [C]-21.13 [Si]-25.56 [Mn]+47.71 [Cr]+16.44 [Ni]; Ar₁=729.2-9.24 [C]+12.13 [Si]-15.56 [Mn]+17.71 [Cr]-46.44 [Ni], where [C], [Si], [Mn], [Cr], [Ni] stand for said content of said elements in steel in wt %.

EFFECT: higher quality of rolled stock.

1 ex

Description

The invention relates to rolling production and can be used in the manufacture of hot rolled broadband (strip) steel.

The technology of hot rolling of low-carbon strip steel is described in sufficient detail, for example, in the book by P. I. Polukhin and others. “Rolling production”, M., “Metallurgy”, 1982, p. 418-420.

проката с σ_в=450…1000 н/мм².A known method of hot rolling of low carbon sheet steel on a continuous multi-batch mill (see RF patent No. 2353442, class B21B 1/26, publ. 10.12.2007) with predetermined temperature conditions for rolling and winding of the strip, in which the strip is rolled to a thickness of 2 , 4 ... 4.0 mm at a temperature in the mill stand VI equal to 1060 ± 20 ° С, and rolling is completed at a temperature of 875 + 15 ° С, and strip winding is performed at Т _cm = 695 ± 15 ° С. However, this method is unsuitable for production from steel with a content of 0.09 ... 0.11 wt.% Carbon at a ratio

rolled products with σ _in = 450 ... 1000 n / mm ² .

The closest analogue to the claimed method is the technology of hot rolling and winding strips on the mill 1700, given in the directory under the editorship of V.I. Zyuzina and A.V. Tretyakova "Technology of rolling production", book 2, M., "Metallurgy", 1991, S. 969-971 and table V. 29.

This technology includes hot rolling of strips, accelerated cooling with specified temperatures and subsequent winding into rolls and is characterized by the fact that the temperature of the end of rolling is taken within 810 ... 930 ° C (depending on the grade of steel), and the temperature of the winding of strips is 580 ... 650 ° With or do not regulate at all, which makes it difficult to obtain strip products with specified strength properties.

The technical task of the present invention is to increase the consumer properties of hot-rolled broadband rolled products by increasing its strength properties, which increases the productivity of this type of rolled products.

проката с σ_в=450…1000 Н/мм², между предварительным и заключительным охлаждениями осуществляют выдержку проката на воздухе, при этом температуру металла в последнем проходе выдерживают выше температуры Аr₃ на 0…25°С, температуру после предварительного ускоренного охлаждения обеспечивают ниже Ar₁ на величину

, а температуру смотки выдерживают ниже Ar₁ на величину

, вычисляя величины Аr₃ и Ar₁ по формулам:To solve this problem in the proposed method for the production of hot-rolled broadband steel, including hot rolling, accelerated cooling of strips with specified temperatures and their subsequent winding into coils, in contrast to the closest analogue for producing a ferritic-martensitic structure from a steel strip with a content of 0.09 ... 0.11 wt.% Carbon, 0.37 ... 0.65% silicon, 1.25 ... 1.60% manganese, 0.48 ... 0.57% chromium and 0.02 ... 0.1% nickel in the ratio

rolled products with σ _in = 450 ... 1000 N / mm ² , between preliminary and final cooling, the rolled products are held in air, while the temperature of the metal in the last pass is maintained at 0 ... 25 ° С higher than Ar ₃ temperature, the temperature after preliminary accelerated cooling is lower Ar ₁ by

and the temperature of the winding is kept below Ar ₁ by

calculating the values of Ar ₃ and Ar ₁ according to the formulas:

Ar ₃ = 879.2-94.24 [C] -21.13 [Si] -25.56 [Mn] +47.71 [Cr] +16.44 [Ni];

Ar ₁ = 729.2-9.24 [C] +12.13 [Si] -15.56 [Mn] +17.71 [Cr] -46.44 [Ni],

where [C], [Si], [Mn], [Cr], [Ni] is the above content of elements in steel, respectively, carbon, silicon, manganese, chromium and nickel, wt.%.

The above mathematical relationships are obtained by processing the experimental data and are empirical.

The essence of the proposed technical solution is to optimize the temperature parameters of rolling and winding for strip steel, which allows to obtain hot-rolled sheet steel with desired strength properties.

When implementing the proposed method of hot rolling, the temperature of the metal in the last pass after preliminary accelerated cooling and winding is taken in accordance with the above dependencies, which are determined for the specific contents of these elements in steel.

Experimental verification of the proposed method was carried out on a broadband hot rolling mill 2000 of OJSC “Magnitogorsk Iron and Steel Works”. To this end, during the hot rolling of steels containing 0.09 ... 0.11 wt.% Carbon, 0.37 ... 0.65% silicon, 1.25 ... 1.60% manganese, 0.48 ... 0.57% chromium and 0.02 ... 0.1% of nickel varied the values Δ _уо and Δ _cm , evaluating the results on the yield of sheet steel of various strength classes.

и

выход листовой стали требуемого класса прочности не превысил 91,0% по причине снижения прочностных свойств. Увеличение значений Δ_уо, и Δ_см более рекомендуемых дало выход листового проката требуемого класса прочности не более 93% по причине ухудшения пластических свойств.The best results (yield of a given strength class in the range of 97.5 ... 99.2%) were obtained when implementing this method. Deviations from the recommended values of Δ _уо , and Δ _cm worsened the achieved indicators. So for example, with

and

the yield of sheet steel of the required strength class did not exceed 91.0% due to a decrease in strength properties. An increase in the values of Δ _уо , and Δ _cm more than recommended gave the yield of sheet metal of the required strength class no more than 93% due to deterioration of plastic properties.

The technology of hot rolling of the sheet, taken as the closest analogue, gave the yield of rolled products of the required strength class in the range of 87.1 ... 89.4%.

Thus, an experimental verification confirmed the acceptability of the technical solution found to achieve the goal and its advantage over a known object.

Feasibility studies have shown that the use of the present invention in the production of hot-rolled sheet steel with specified strength properties will reduce production costs by almost 1.2 times with a corresponding reduction in the cost of rental.

Concrete example

.1. Steel with a content of 0.11 wt.% Carbon, 0.65% silicon, 1.60% manganese, 0.57% chromium and 0.03% nickel is rolled at a 2000 broadband hot rolling mill of OJSC Magnitogorsk Iron and Steel Works the value of σ _in = 700 N / mm ² when

.

The chemical composition of steel contains the maximum statement the percentage of alloying elements with an average value of tensile strength σ _in .

,

.Steel is rolled at

,

.

Since: Ar ₃ = 879.2-94.24 [C] -21.13 [Si] -25.56 [Mn] +47.71 [Cr] +16.44 [Ni] = 879.2-94 , 24 * 0.11-21.13 * 0.65-25.56 * 1.60 + 47.71 * 0.57 + 16.44 * 0.03 = 841.89 ° C and Ar ₁ = 729, 2-9.24 [C] +12.13 [Si] -15.56 [Mn] +17.71 [Cr] -46.44 [Ni] = 729.2-9.24 * 0.11 + 12 , 13 * 0.65-15.56 * 1.60 + 17.71 * 0.57-46.44 * 0.03 = 719.87 ° C.

Temperature rolling:

The temperature of the end of rolling t _kn = Ar ₃ + (0 ... 25 ° C) = 841.89 + (0 ... 25) = 841.89 ... 866.89 ° C,

The temperature after preliminary accelerated cooling t _yo = Ar ₁ -Δ _уo = 719.87-105.16 = 614.71 ° С,

The winding temperature t _cm = Ar ₁ -Δ _cm = 719.87-497.5 = 222.37 ° C.

.2. Steel with a content of 0.11 wt.% Carbon, 0.65% silicon, 1.60% manganese, 0.57% chromium and 0.1% nickel is rolled at a 2000 broadband hot rolling mill of OJSC Magnitogorsk Iron and Steel Works the value of σ _in = 1000 N / mm ² when

.

The chemical composition of the steel contains the maximum declared percentage of alloying elements with a maximum value of tensile strength σ _in .

,

.Steel is rolled at

,

.

Since: Ar ₃ = 879.2-94.24 [C] -21.13 [Si] -25.56 [Mn] +47.71 [Cr] +16.44 [Ni] = 879.2-94 24 * 0.11-21.13 * 0.65-25.56 * 1.60 + 47.71 * 0.57 + 16.44 * 0.1 = 843.04 ° C and Ar ₁ = 729, 2-9.24 [C] +12.13 [Si] -15.56 [Mn] +17.71 [Cr] -46.44 [Ni] = 729.2-9.24 * 0.11 + 12 13 * 0.65-15.56 * 1.60 + 17.71 * 0.57-46.44 * 0.1 = 716.62 ° C.

Temperature rolling:

The temperature of the end of rolling t _kn = Ar ₃ + (0 ... 25 ° C) = 843.04 + (0 ... 25) = 843.04 ... 868.04 ° C,

The temperature of accelerated cooling after pre t _yo = Ar ₁ -Δ _yo = 716,62-147,16 = 569,46 ° C,

Winding temperature t _cm = Ar ₁ -Δ _cm = 716.62-533.5 = 183.12 ° C.

.3. At the 2000 broadband hot rolling mill of OJSC Magnitogorsk Iron and Steel Works, steel is rolled with a content of 0.09 wt.% Carbon, 0.37% silicon, 1.25% manganese, 0.48% chromium and 0.02% nickel, the value of σ _in = 450 N / mm at

.

The chemical composition of the steel contains the minimum declared percentage of alloying elements with a minimum value of tensile strength σ _in .

,

.Steel is rolled at

,

.

Since: Ar ₃ = 879.2-94.24 [C] -21.13 [Si] -25.56 [Mn] +47.71 [Cr] +16.44 [Ni] = 879.2-94 24 * 0.09-21.13 * 0.37-25.56 * 1.25 + 47.71 * 0.48 + 16.44 * 0.02 = 854.18 ° C and Ar ₁ = 729, 2-9.24 [C] +12.13 [Si] -15.56 [Mn] +17.71 [Cr] -46.44 [Ni] = 729.2-9.24 * 0.09 + 12 , 13 * 0.37-15.56 * 1.25 + 17.71 * 0.48-46.44 * 0.02 = 720.98 ° C.

Temperature rolling:

The temperature of the end of rolling t _kn = Ar ₃ + (0 ... 25 ° C) = 854.18 + (0 ... 25) = 854.18 ... 879.18 ° C,

The temperature of accelerated cooling after pre t _yo = Ar ₁ -Δ _yo = 720,98-1,41 = 719,57 ° C,

The winding temperature t _cm = Ar ₁ -Δ _cm = 720.98-288.75 = 432.23 ° C.

Getting rolled with a minimum value of tensile strength σ _in = 450 N / mm ² requires an increased temperature of the winding, which is confirmed by the recommended rolling mode.

.4. At the 2000 broadband hot rolling mill of OJSC Magnitogorsk Iron and Steel Works, steel is rolled with a content of 0.1 wt.% Carbon, 0.5% silicon, 1.40% manganese, 0.52% chromium and 0.06% nickel, the value of σ _in = 700 N / mm ² when

.

The chemical composition of the steel contains the average declared percentage of alloying elements with an average value of tensile strength σ _in .

,

.Steel is rolled at

,

.

Since: Ar ₃ = 879.2-94.24 [C] -21.13 [Si] -25.56 [Mn] +47.71 [Cr] +16.44 [Ni] = 879.2-94 24 * 0.1-21.13 * 0.5-25.56 * 1.40 + 47.71 * 0.52 + 16.44 * 0.06 = 849.22 ° C and Ar ₁ = 729, 2-9.24 [C] +12.13 [Si] -15.56 [Mn] +17.71 [Cr] -46.44 [Ni] = 729.2-9.24 * 0.1 + 12 13 * 0.5-15.56 * 1.40 + 17.71 * 0.52-46.44 * 0.06 = 718.98 ° C.

Temperature rolling:

The temperature of the end of rolling t _kn = Ar ₃ + (0 ... 25 ° C) = 849.22 + (0 ... 25) = 849.22 ... 874.22 ° C,

The temperature of accelerated cooling after pre _YO t -Δ ₁ = Ar _yo = 718,98-105,16 = 613,82 ° C,

Winding temperature t _cm = Ar ₁ -Δ _cm = 718.98-497.5 = 221.48 ° C.

.5. At the 2000 broadband hot rolling mill of OJSC Magnitogorsk Iron and Steel Works, steel is rolled with a content of 0.09 wt.% Carbon, 0.37% silicon, 1.25% manganese, 0.48% chromium and 0.02% nickel, the value of σ _in = 1000 N / mm ² when

.

The chemical composition of steel contains the minimum declared percentage of alloying elements with a maximum value of tensile strength σ _in .

, и

.Steel is rolled at

, and

.

Since: Ar ₃ = 879.2-94.24 [C] -21.13 [Si] -25.56 [Mn] +47.71 [Cr] +16.44 [Ni] = 879.2-94 24 * 0.09-21.13 * 0.37-25.56 * 1.25 + 47.71 * 0.48 + 16.44 * 0.02 = 854.18 ° C and Ar ₁ = 729, 2-9.24 [C] +12.13 [Si] -15.56 [Mn] +17.71 [Cr] -46.44 [Ni] = 729.2-9.24 * 0.09 + 12 , 13 * 0.37-15.56 * 1.25 + 17.71 * 0.48-46.44 * 0.02 = 720.98 ° C.

Temperature rolling:

The temperature of the end of rolling t _kn = Ar ₃ + (0 ... 25 ° C) = 854.18 + (0 ... 25) = 854.18 ... 879.18 ° C,

The temperature of accelerated cooling after pre _YO t -Δ ₁ = Ar _yo = 720,98-147,16 = 573,82 ° C,

Winding temperature t _cm = Ar ₁ -Δ _cm = 720.98-533.5 = 187.48 ° C.

Claims (1)

A method for the production of hot-rolled broadband steel with σ _in = 450 ... 1000 N / mm ² and a ratio of σ _t / σ _in ≤0.8 from a steel strip of a ferritic-martensitic structure with a content of 0.09 ... 0.11 wt.% Carbon, 0, 37 ... 0.65 wt.% Silicon, 1.25 ... 1.60 wt.% Manganese, 0.48 ... 0.57 wt.% Chromium and 0.02 ... 0.1 wt.% Nickel, including hot rolling, accelerated cooling of strips with predetermined temperatures and their subsequent winding into rolls, at the same time, preliminary and final accelerated cooling are performed, between which rolling is held in air, metal temperature during rolling in the final pass is kept in the range of Ar ₃ - (Ar ₃ + 25 ° C), the temperature after accelerated cooling prior provide Ar ₁ below the amount

, and the temperature of the winding is kept below Ar ₁ by

while the values of Ar ₃ and Ar ₁ are calculated by the formulas
Ar ₃ = 879.2-94.24 [C] -21.13 [Si] -25.56 [Mn] +47.71 [Cr] +16.44 [Ni];
Ar ₁ = 729.2-9.24 [C] +12.13 [Si] -15.56 [Mn] +17.71 [Cr] -46.44 [Ni],
where [C], [Si], [Mn], [Cr], [Ni] is the above content of elements in steel, respectively, carbon, silicon, manganese, chromium and nickel, wt.%.