RU2283875C2 - Calibrated round merchant shapes in bars - Google Patents

Abstract

FIELD: metallurgy; production of merchant shapes from medium-carbon steel at high machinability for manufacture of shock absorber rods for automobiles.

SUBSTANCE: proposed method enhances machinability at optimum ratio of strength, ductility and plasticity, minimum level of anisotropy at simultaneous improved characteristics of hardenability to level of through hardenability of rods to 30 mm. Proposed bars are made from medium-carbon steels containing carbon and alloying elements and possessing preset parameters of metallurgical quality, structure, mechanical properties, hardenability and machinability; medium-carbon steel contains the following components, mass-%: carbon, 0.42-0.50; manganese, 0.50-0.80; silicon, 0.17-0.37; sulfur, 0.020-0.040; phosphorus, 0.001-0.030; aluminum, 0.03-0.05; calcium, 0.001-0.010; oxygen, 0.001-0.015; chromium, no more than 0.25; nickel, no more than 0.025; copper, no more than 0.25; molybdenum, no more than 0.10; arsenic, no more than0.08; nitrogen, no more than 0.015; the remainder being iron and unavoidable admixtures. Ratio of oxygen and calcium , as well as calcium and sulfur is determined by the following dependances: oxygen/calcium= 1-4.5 and calcium/sulfur≥0.065. Nonmetallic inclusions of sulfides have double-layer structure: sulfide with oxide envelope; curvature of bars does not exceed 1.0 mm/m; rolled bars have plastic ferrite-pearlite structure at actual size of grain of 5-8; diameter of bars ranges from 10 to 30 mm; decarbonized layer is no more than 1.5% of diameter; hardness of billet is 229-255; rupture strength no less than 640 Mpa; relative elongation no less than 6% and relative reduction no less than 30%.

EFFECT: improved machinability characteristics at optimum ductility and strength; improved hardenability characteristics.

1 ex

Description

The invention relates to the field of metallurgy, in particular to the production of long products in bars, calibrated, round, from medium carbon steel with increased machinability used for the manufacture of automobile shock absorber rods.

Known long products of round steel made of steel (wt.%): Carbon 0.38-0.47%, manganese 0.8-1.2%, silicon 0.17-0.37%, vanadium 0.08-0.18%, boron 0.001 -0.005%, nitrogen 0.005-0.025%, sulfur 0.036-0.080%, calcium 0.001-0.010%, the rest, provided that the ratio of manganese to calcium is 100-1100. (USSR author's certificate SU 1689424 A1, C 22 C 38/60 of 11/07/1989 Bull. No. 41). The disadvantages of this steel are the relative high nitrogen content and the absence of elements in the composition that protect boron from binding to nitrides, which in some cases will not allow the authors claimed effect to increase the hardenability characteristics.

Known long products made of round steel containing (wt.%): Carbon 0.42-0.50%, silicon 0.17-0.37%, manganese 0.50-0.80%, sulfur - not more than 0.040% phosphorus - not more than 0.035%, the rest is iron. Impurities: chromium - not more than 0.25%, nickel - not more than 0.30%, arsenic - not more than 0.08%, nitrogen - not more than 0.008%, copper - not more than 0.30% (Marochnik of steels and alloys, Edited by A.S. Zubchenko. M., Mechanical Engineering, 2003, p. 102).

The closest in technical essence and the achieved effect to the proposed invention is the calibrated rolled steel, round, made of steel containing carbon and alloying elements, having specified parameters of steel quality for non-metallic inclusions, structure, mechanical properties, hardenability and machinability by cutting (RU 2156312 C1, 09/20/2000).

The most important requirement for long products, round, from mild steel is to provide improved machinability by cutting, while ensuring a favorable ratio of strength, ductility and toughness, a minimum level of anisotropy of mechanical properties and at the same time increase the hardenability characteristics while ensuring through hardenability of long products with a diameter of up to 30 mm .

The technical result of the invention is the provision of rational conditions for machining while ensuring homogeneous mechanical properties along the rolled section.

In order to achieve a technical result, calibrated rolled stock is invented, calibrated round in bars, smelted from medium-carbon steel containing carbon and alloying elements, having predetermined parameters of steel quality for non-metallic inclusions, structure, mechanical properties, hardenability and machinability by cutting, while steel contains the following ratio of components in wt.%:

carbon 0.42-0.50 manganese 0.50-0.80 silicon 0.17-0.37 sulfur 0,020-0,040 phosphorus 0.001-0.030 aluminum 0.03-0.050 calcium 0.001-0.010 oxygen 0.001-0.015 chromium no more than 0.25 nickel up to 0.25 copper no more than 0.25 molybdenum no more than 0.10 arsenic no more than 0.08 nitrogen no more than 0.015 iron and inevitable impurities rest,

when fulfilling the ratios: oxygen / calcium = 1-4.5; calcium / sulfur ≥0.065, non-metallic inclusions of sulfides have a two-layer structure: sulfide with an oxide shell, rolled metal has a lamellar ferrite-pearlite structure with a real grain size of 5-8 points, diameter from 10 to 30 mm, curvature not more than 1.0 mm / m , the decarburized layer is not more than 1.5% of the rolled diameter, hardness 229-255 HB, tensile strength at least 640 MPa, elongation at least 6%, relative narrowing at least 30%.

The given combinations of alloying elements (item 1) make it possible to obtain in a finished product (a shock absorber rod with a diameter of up to 23 mm), after turning, quenching with high-frequency currents and subsequent grinding, a ferrite-pearlite fine structure with a favorable combination of strength and ductility characteristics.

Carbon is introduced into the composition of this steel in order to ensure a given level of strength and ductility. The upper limit of the carbon content (0.50%) is due to the need to ensure the required level of ductility of steel, and the lower - respectively 0.42% - to ensure the required level of strength of this steel.

Manganese is used, on the one hand, as a hardener of a solid solution, on the other hand, as an element that significantly increases the stability of supercooled austenite. Moreover, the upper level of manganese content - 0.80%, is determined by the need to ensure the required level of ductility of steel, and the lower - 0.50%, by the need to provide the required level of strength of steel.

Silicon refers to ferrite-forming elements. The lower limit for silicon - 0.17% due to the technology of deoxidation of steel. A silicon content above 0.37% will adversely affect the ductility characteristics of steel.

Sulfur determines the level of ductility of steel. The upper limit (0.020%) is due to the need to obtain a given level of ductility and toughness of steel, and the lower limit (0.005%) is due to issues of manufacturability.

Phosphorus is an element that contributes to an increase in steel cutting performance. At the same time, the upper level of phosphorus content - 0.030% is due to the need to prevent the development of processes of reversible temper brittleness of steel, as well as to ensure the required level of ductility of steel, and the lower - 0.0010%, respectively, by the need to ensure the required level of strength and machinability by steel cutting.

Calcium is an element that modifies non-metallic inclusions. The upper limit (0.010%), as in the case of sulfur, is due to the need to obtain a given level of ductility and toughness of steel, and the lower (0.001%) limit is due to issues of manufacturability.

Oxygen, forming an oxide film on sulfides, helps to increase the machinability of steel by cutting while maintaining a high complex of consumer properties of steel. Moreover, the upper level of oxygen content - 0.015% is due to the need to ensure the required level of ductility of steel, and the lower - 0.001%, respectively, the need to provide the required level of strength and machinability by cutting steel.

Ratios:

The ratio of oxygen / calcium = 1 ÷ 4.5 is responsible for the possibility of the formation of a sandwich-non-metallic inclusion. Moreover, the upper limit of the ratio of 4.5 is due to the need to ensure the required level of ductility of steel, and the lower one is 1, respectively, the possibility of the formation of a two-layer sandwich non-metallic inclusion.

The calcium / sulfur ratio of ≥0.065% determines the conditions for the formation of globular nonmetallic inclusions (sulfides). If this ratio is fulfilled, then the sulfides are globular, otherwise elongated sulfides are present in the steel. which increases the anisotropy of the properties of steel and worsens the strength-toughness ratio, especially strongly in the transverse direction of the car.

Comparative analysis with the prototype allows us to conclude that the claimed composition differs from the known one by the introduction of new components - aluminum, calcium and oxygen, as well as the ratios: oxygen / calcium = 1 ÷ 4.5 and calcium / sulfur ≥0.065%

Thus, the claimed technical solution meets the criterion of "novelty."

The analysis of patent and scientific and technical information did not reveal solutions having a similar set of features that would achieve a similar effect - improving the machinability of cutting while maintaining a favorable ratio of strength - ductility and toughness of steel.

Therefore, the claimed combination of features meets the criterion of "significant differences".

The following is an example implementation of the invention, not excluding others in the scope of the claims.

Smelting of the test steel (chemical composition in wt.%: Carbon - 0.48%, manganese - 0.72%, silicon - 0.32%, sulfur - 0.034%, phosphorus - 0.022%, aluminum - 0.037%, calcium - 0 , 0025%, oxygen - 0.010%) was carried out in 150-ton steel arc furnaces (DSP-150, transformer power 80 mVA) using 60% metallized pellets and 40% metal scrap in the charge, which ensures a mass fraction of nitrogen before being released from Particleboard is not more than 0.003%, as well as a low content of color impurities. Preliminary alloying of metal with manganese and silicon was carried out in a ladle when discharged from particleboard (Release of peroxidized metal into a ladle. Metal deoxidation — when released by aluminum, ferrosilicon — deoxidation, alloying — FeMn (SiMn), FeCr). After release, the metal was purged with argon through the bottom purge unit for 5-7 minutes. Then evacuation on a portion vacuum, while doping (fine) - carbon, manganese and silicon. After evacuation - processing on a ladle furnace. 15-30 minutes before the end of the treatment, an oxidizing agent is introduced, in this case, oxidized pellets. Then again introduced aluminum (wire). For 10-15 minutes, treatment with flux-cored wires with silicocalcium and pure sulfur. Steel casting was carried out on a high-quality radial type continuous casting machine in NLZ 300 × 360 mm with a draw speed of 0.6-0.7 m / min. During casting, the jet was protected from secondary oxidation as follows:

- steel-ladle-tundish - dip tube with argon feed

- industrial ladle - slag-forming mixture

- tundish-crystallizer - immersion cup (corundum-graphite)

- in the mold - slag-forming mixture.

After casting and cutting to a measured length, continuously cast billets were cooled in controlled cooling furnaces. Next, the ingots were rolled in a mill 700 into a billet (170 mm square). The entire initial billet was subjected to dressing, descaling, and surface control. The billets were heated before rolling in two walking-hearth furnace furnaces. The heating temperature of the billet is 900 ° C, which ensures a 15% reduction in energy costs and significantly reduces the decarburization of rolled products. Dross from the surface of the workpiece was removed with high-pressure water at a descaling unit. Rolling was carried out in continuous lines - small-grade and medium-grade. High rigidity of the stands, automatic adjustment of the speed of the stands, and a loop control system in the finishing group of the small-grade line made it possible to obtain high-precision rolled products. Finishing of the rolling was carried out off-stream.

As a result of hot rolling and subsequent calibration, we obtain long products ⌀22.5 mm, length - 5900 mm, bar curvature - not more than 0.7 mm / m. Lamellar perlite structure, decarburized layer 0.05 mm deep. the real grain score is 7, the hardness of the workpiece is 229-241 HB, the tensile strength is 680 MPa, the elongation is 9%, the relative narrowing is 42%

Ratio: oxygen / calcium = 4.0, calcium content - 0.0025%, oxygen - 0.010%; calcium / sulfur = 0.074, calcium content - 0.0025%, sulfur - 0.034%.

Implementation of the proposed method for the production of long products from medium carbon steel with increased machinability, providing two-layer sandwich-non-metallic inclusions, guaranteeing, on the one hand, providing improved cutting characteristics, on the other hand, a favorable ratio of ductility and toughness of steel.

Claims (1)

Long products calibrated, round in bars, smelted from medium-carbon steel containing carbon and alloying elements, having predetermined parameters of steel quality for non-metallic inclusions, structure, mechanical properties, hardenability and machinability by cutting, characterized in that the steel contains the following ratio of components, wt. %: Carbon 0.42-0.50 Manganese 0.50-0.80 Silicon 0.17-0.37 Sulfur 0,020-0,040 Phosphorus 0.001-0.030 Aluminum 0.03-0.050 Calcium 0.001-0.010 Oxygen 0.001-0.015 Chromium No more than 0.25 Nickel Up to 0.25 Copper No more than 0.25 Molybdenum No more than 0.10 Arsenic No more than 0,08 Nitrogen No more than 0.015 Iron and inevitable impurities Rest when the relations oxygen / calcium = 1-4.5; calcium / sulfur ≥0.065, non-metallic inclusions of sulfides have a two-layer structure: sulfide with an oxide shell, rolled metal has a lamellar ferrite-pearlite structure with a real grain size of 5-8 points, diameter from 10 to 30 mm, curvature not more than 1.0 mm / m the decarburized layer is not more than 1.5% of the diameter of the rolled product, hardness is 229-255 HB, the tensile strength is not less than 640 MPa, the elongation is not less than 6%, the relative narrowing is not less than 30%.