RU2479645C1 - Round hot-rolled bar stock - Google Patents

Abstract

FIELD: metallurgy.

SUBSTANCE: hot-rolled bar stock is obtained from steel containing the following components, wt %: carbon 0.31 - 0.35, manganese 0.75 - 0.95, silicon 0.30 - 0.45, chrome 0.80 - 1.2, molybdenum 0.50-0.65, nickel 0.30 - 0.50, aluminium 0.015-0.040, iron and inevitable impurities: sulphur of not more than 0.010, copper of not more than 0.20, phosphorus of not more than 0.015, and nitrogen of not more than 0.010. Rolled stock has macrostructure: central porosity, point non-homogeneity, segregation square of not more than 2 points for each type, sub-shrinkage segregation of not more than 1 point; the following is excluded: freckle-type segregation, edge freckle-type segregation, subsurface pinholes, intergranular cracks, non-metallic inclusions: oxides and silicates of not more than 4 points, non-deformable silicates of not more than 4.5 points, and sulphides of not more than 4 points. Size of austenitic grain comprises maximum 6 points. Rolled stock is subject to heat treatment by heating to 670-690°, exposure during 22 hours, cooling in the furnace to 600°, and then, cooling in the air so that the following mechanical properties are obtained: ultimate strength of not less than 1050 N/mm², yield strength of not less than 950 N/mm², relative elongation of not less than 15%, relative constriction of not less than 55%, impact strength of not less than 111 J/cm², and hardness of not more than 255 HB.

EFFECT: providing high mechanical properties.

1 tbl, 1 ex

Description

The invention relates to the field of metallurgy, in particular to the production of hot-rolled long products in bars, round, with a diameter of 210 mm, from high-quality structural steel, which can be used in oil production for products operating with high mechanical loads, namely for drilling joints.

Closest to the offer is hot-rolled bar stock in bars, round, which is obtained from steel grade 30XMA according to GOST 4543-71, containing in wt.%: C - 0.26-0.33, Mn - 0.40-0.70 , Si - 0.17-0.37, Cr - 0.80-1.10, Mo - 0.15-0.25, S - not more than 0.025, P - not more than 0.025, Cu - not more than 0.30 , Ni - not more than 0.30, iron and inevitable impurities - the rest.

Famous long products hot rolled in bars, round has:

- macrostructure: central porosity, point heterogeneity, segregation square no more than 2 points for each type, shrink segregation no more than 1 point, total spotted segregation, marginal spotted segregation, subcortical bubbles, intercrystalline cracks are not allowed; grain no larger than No. 5; tensile strength not less than 930 N / mm ² , yield strength not less than 735 N / mm ² , elongation not less than 12%, relative narrowing not less than 50%, impact strength (KCU) not less than 88 J / cm ² , hardness not more than 229 HB.

The well-known long products are made of structural alloyed high-quality steel grade 30XMA according to GOST 4543-71, intended, in particular, for the manufacture of shafts, axles, gears and other large critical parts.

A disadvantage of the known long products hot rolled in bars, round are reduced mechanical properties. This is especially true of plastic properties (elongation of at least 12%, relative contraction of at least 50%, impact strength (KCU) of at least 88 J / cm ² ). Plastic materials are more reliable in operation, since they are less likely to cause dangerous brittle fracture.

The claimed invention solves the problem of creating high-quality high-quality rolled products in round bars, the implementation of which allows to achieve a technical result, which consists in the possibility of obtaining high-quality long-rolled products in bars, round, with a diameter of 210 mm, not inferior to the known macrostructure with higher mechanical properties and allowing to use it for products operating in oil production with high mechanical loads, namely for drills s connections.

The essence of the invention lies in the fact that in long products hot rolled in bars, round of high-quality structural steel, made with specified parameters of mechanical properties, purity for non-metallic inclusions, the magnitude of the austenitic grain, macrostructure, namely: central porosity, point heterogeneity, segregation square is not more than 2 points for each species, shrink liquation no more than 1 point, total spotted segregation, marginal spotted segregation, subcortical vesicles, intercrystalline are not allowed cracks, new is that rolled products are obtained from steel containing carbon, manganese, silicon, chromium, molybdenum, nickel, aluminum, iron and inevitable impurities, in the following ratio, wt.%: carbon 0.31-0.35; manganese 0.75-0.95; silicon 0.30-0.45; chrome 0.80-1.2; molybdenum 0.50-0.65; nickel 0.30-0.50; aluminum 0.015-0.040; iron and unavoidable impurities, the rest, and as inevitable impurities, steel contains a mass fraction of elements, in%: sulfur no more than 0.010, copper no more than 0.20, phosphorus no more than 0.015, nitrogen no more than 0.010, while rolling has a temporary resistance of at least 1050 N / mm ² , yield strength not less than 950 N / mm ² , elongation not less than 15%, relative narrowing not less than 55%, impact strength not less than 111 J / cm ² , hardness not more than 255 HB, austenitic grain size not more than 6 numbers, purity by non-metallic inclusions: oxides and silicates not more than 4 points, s non-deforming liquates not more than 4.5 points, sulfides not more than 4 points, in addition, the rolling is subjected to heat treatment, namely heating to a temperature of 670-690 °, holding for 22 hours, cooling in an oven to 600 °, then cooling in calm air to a temperature the environment.

The technical result is achieved as follows.

The qualitative and quantitative composition of the steel in the declared long products by hot-rolled in bars, round due to the following.

Iron is the main component of steel.

Carbon reinforces steel. Carbon is introduced into the composition of the claimed steel in order to ensure a given level of its strength and hardness. In this case, carbon is involved in two processes. The first process is the formation of graphite inclusions in the steel structure, the second is the formation of particles of the carbide phase in a metal matrix. When the carbon content is less than 0.31%, an insufficient amount of both free carbon and carbides is formed, which leads to increased wear of the products during operation and a decrease in the strength properties of the material. When the carbon content is more than 0.34%, an excess amount of particles of the carbide phase of an unfavorable shape is released, which leads to a decrease in the plastic properties of steel.

In the composition of the declared steel, the amount of silicon is in the range of 0.30-0.45%. Silicon refers to ferrite-forming elements. Silicon dissolves in ferrite and increases strength, especially increases yield strength. Silicon contributes to the release of carbon in free form in accordance with a stable iron-carbon system, which significantly increases the wear resistance of the alloy. The quantitative content of silicon in the composition of the steel corresponds to the quantitative content of carbon. For the quantitative carbon content in the declared steel, silicon in an amount of less than 0.30% does not significantly affect the graphitization process, as a result of which carbon is in a bound state, which leads to a deterioration in the hardness of the steel, to significant wear of products during operation under intense friction. When the silicon content is more than 0.45% in the steel structure, an increased number of large inclusions of graphite of an unfavorable shape is observed, which also negatively affects the hardness characteristics, worsens the strength and plastic properties of the material. Since silicon is a deoxidizing agent in steelmaking, combining with oxygen reduces its harmful effect by forming silicates in the finely dispersed phase, which increase the number of crystallization centers and contribute to the formation of a fine-grained steel structure, which increases its quality and mechanical properties. Moreover, for the claimed steel, this is ensured with a range of silicon contents in the steel of 0.30-0.45%, which is optimal.

In addition, silicon increases the resistance of steel to pitting and crevice corrosion, improves the workability of steel, which in the claimed composition of the steel is provided with the same quantitative silicon content.

Manganese, molybdenum and chromium are used, on the one hand, as solid solution hardeners, and on the other hand, as elements that increase the stability of supercooled austenite of steel. In the claimed composition, manganese and molybdenum steel were taken in the following quantitative limits: (0.75-0.95%) manganese, (0.50-0.65%) molybdenum, which provides the required combination of strength and ductile properties in combination with increased influence molybdenum on the stability of supercooled austenite.

Manganese (0.75-0.95%), dissolving in a metal base, increases hardness, stabilizes perlite. Within the declared limits, manganese increases the strength of steel (temporary resistance and yield strength), without reducing ductility, and reduces the red-brittleness of steel caused by the influence of sulfur. This is because manganese helps to reduce the content of iron sulfide, since it forms manganese sulfide with sulfur, which is present in the composition of the declared steel as an inevitable impurity. Manganese sulfide particles are located in the form of individual inclusions that are deformed and are elongated along the rolled metal. In addition, forming a sulfide compound with sulfur, manganese binds it and reduces the negative effect of sulfur on the corrosion resistance of steel. Moreover, being present in steel in the declared amount, manganese, in addition to stabilizing the austenitic structure, increases the solubility of nitrogen in steel and improves its overall corrosion resistance.

When the manganese content is less than 0.75%, the presence of ferrite inclusions is observed in the steel structure, which leads to a decrease in the hardness and wear resistance of the alloy. When the manganese content is more than 0.95%, the plastic properties of the steel decrease due to local supersaturation of the ferrite component of perlite with manganese.

Molybdenum is effective in increasing strength and in the composition of the steel in the claimed invention has a significant effect on the formation of a uniform steel structure. Molybdenum in the presence of chromium forms carbide (Mo, Fe) ₂₃ C ₆ . The presence of molybdenum in the declared range (0.50-0.65%) increases the hardenability of steel, which allows to obtain a uniform and fine-grained structure, increases the creep resistance of steel, inhibits the growth and coagulation of carbides. The grain size has a significant effect on the mechanical properties of steel: the smaller the grain, the higher the quality of the steel. In the claimed invention, the size of the austenitic grain is not larger than 6 numbers (in the prototype, not larger than 5 numbers). Since an excess amount of molybdenum can lead to the development of aging processes with the release of the κ phase, which is similar in its negative effect on ductility, and impact strength with the σ phase, in the claimed invention the maximum amount of molybdenum in steel is limited to 0.65%.

When the molybdenum content in the steel is less than 0.50%, the number of formed compounds decreases, the structure of the steel is not uniform, which leads to a decrease in the strength and plastic properties of the material.

In addition, molybdenum enhances corrosion resistance, especially resistance to chloride pitting and crevice corrosion, and also increases the solubility of nitrogen in steels, which in the claimed steel is provided by the molybdenum content in the range 0.50-0.65%.

Chrome increases the hardness and strength of steel with a slight decrease in ductility. Chromium significantly affects the ultimate solubility of nitrogen in steel, the measure of stabilization of austenite and the value of the stationary potential. In addition, in the declared amount, chromium completely dissolves in cementite, forming complex carbides of the type (Fe, Cr) ₃ C, contributes to a high and uniform hardness, wear-resistant surface. When the chromium content is less than 0.8%, the hardness and wear resistance of the steel decreases. With a content of more than 1,200%, carbides are enlarged, their number increases, which leads to a decrease in the plastic properties of steel.

In total: the upper level of manganese is 0.95%, molybdenum is 0.65% and chromium is 1.20% is determined by the need to ensure the required level of ductility of steel while maintaining the hardness requirements, and the lower level of manganese is 0.75 %, molybdenum - 0.50% and chromium - 0.80%, respectively, is determined by the need to ensure the required level of strength of this steel.

Aluminum in the composition of the declared steel in the specified range of 0.015-0.040% provides an increase in strength properties, impact strength. Aluminum is a deoxidizing and modifying element. In addition, it binds nitrogen to nitrides. When the aluminum content is less than 0.015%, its effect is weak, the mechanical properties of steel are reduced. An increase in the aluminum content above 0.040% leads to heterogeneity of the microstructure of the steel, which, in turn, leads to a decrease in the ductility and toughness of the metal.

Nickel is part of the declared steel in the amount of 0.30-0.50%. Nickel positively affects the characteristics of the strength of the declared steel, hardness, reduces the tendency to brittle fracture, increases the dispersion of carbides, increases the resistance of steel to oxidation when heated and its strength at high temperatures. In addition, nickel in the declared amount neutralizes the harmful effects of copper (not more than 0.20%), which is also part of the declared steel in the form of impurities, which include the possibility of cracking on the surface during hot rolling. Nickel also contributes to the absorption of gases by the metal during the smelting process, in particular hydrogen, which causes the formation of gas bubbles in the ingots and causes coarse-grained primary structure.

Sulfur, copper, phosphorus, nitrogen are part of the steel in the form of impurities.

Copper (not more than 0.20%) within the specified limits provides an increase in mechanical properties and wear resistance at high temperatures and heat transfer. The lower limit is not defined, as it is due to issues of manufacturability.

Sulfur globularizes sulfide inclusions and is involved in the formation of the level of strength and ductility of steel. When the content in the declared steel in an amount of not more than 0.010% sulfur does not adversely affect the ductility, toughness and corrosion resistance of rolled steel.

Phosphorus is present in an impurity in an amount of not more than 0.015%. Phosphorus affects the level of ductility of steel and its tendency to reversible temper brittleness. The phosphorus content in the claimed steel composition of not more than 0.015% has a positive effect on obtaining a given level of strength, ductility and temper brittleness of steel. The lower limit is not defined, as it is due to issues of manufacturability.

Nitrogen enters the steel during smelting and is in the steel in the form of non-metallic inclusions of nitrides, located in defects (shells, cracks). The nitrogen content in the composition of the declared steel in an amount of not more than 0.010% does not adversely affect the receipt of a given level of ductility and toughness of steel.

It is known that non-metallic inclusions, being stress concentrators, can significantly reduce the mechanical properties of rolled metal. They reduce the endurance limit, viscosity, reduce resistance to brittle fracture. In the claimed invention, purity is achieved by non-metallic inclusions, which provides rolled products with high mechanical properties, namely: oxides and silicates of not more than 4 points, non-deforming silicates of not more than 4.5 points, sulfides of not more than 4 points.

A significant increase in the strength of steel, in addition to alloying, is achieved by heat treatment, since under the influence of temperature, heating, cooling, the structure, grain size and solubility of the alloying elements of steel change. In the claimed invention, the rolling is subjected to heat treatment, namely heating to a temperature of 670-690 °, holding for 22 hours, cooling in an oven to 600 °, then cooling in still air to ambient temperature. As a result, the claimed structural and mechanical properties of the rental are provided.

Thus, from the foregoing, it follows that the implementation of the claimed invention allows to achieve a technical result, consisting in the possibility of obtaining long products hot rolled in bars, round, with a diameter of 210 mm, not inferior to the known macrostructure, having higher mechanical properties and allowing its use in oil production for products operating under high mechanical loads, namely for drilling joints.

Information confirming the possibility of implementing the claimed invention with the receipt of the claimed technical result is shown in the example.

An example embodiment of the invention.

Smelting of the investigated steel was performed with a chemical composition in wt.%: C = 0.33; Mn = 0.85; Si = 0.40; Cr = 0.98; Ni = 0.42; Cu = 0.19; Mo = 0.57; Al = 0.023; N = 0.0087; S = 0.009, P = 0.012.

Smelting was carried out in 80-ton arc steel-smelting furnaces (DSP) using up to 40% liquid cast iron in a charge.

The preliminary alloying of the metal with manganese and silicon was carried out in a ladle upon discharge from particleboard. After release, the metal was purged with argon through the bottom purge unit, during which the steel was deoxidized by aluminum.

Further metal processing was performed at the out-of-furnace steel processing unit (UVOS), where refining slag is added with an additive of lime and fluorspar to reduce non-metallic inclusions and reduce gases in steel; purging metal with argon through the bottom purging unit, desulfurization, heating the metal to the required temperature, adjusting the chemical composition of the metal with the addition of lumpy ferroalloys and cored wire with fillers.

At the end of the treatment, the metal was evacuated in a vacuum degassing unit. In the process of evacuation, gas is removed.

During evacuation, a final adjustment was made in chemical composition.

Casting was carried out in molds with argon jet protection.

As a result of hot rolling, long products with a diameter of 210 mm and a length of 4800 mm were obtained.

Rolled products were subjected to heat treatment (high tempering) in an annealing furnace with a sliding hearth according to the regime: heating to a temperature of (680 ± 10) ° С, holding for 22 hours, cooling in an oven to 600 ° С for one hour, then cooling in calm air.

Rolled products are delivered with surface turning without decarburization, with group 1 surface quality in accordance with GOST 4543-71.

Long products with a diameter of 210 mm:

- macrostructure: central porosity 1 point, point heterogeneity 1 point, segregation square 1 point, shrink segregation 0 points, total spotted segregation 0 points, marginal spotted segregation 0 points, subcortical bubbles 0 points, intergranular cracks 0 points;

- the size of austenitic grain according to GOST 5639-82 - number 7;

- mechanical properties, determined on samples made of heat-treated preforms (quenching at a temperature of 850 ° C cooling in oil, tempering at a temperature of 600 ° C cooling in oil): temporary resistance 1120 N / mm ² , yield strength 1025 N / mm ² , elongation of 15.5%, relative narrowing of 57.0%, impact strength (KCV) 115 J / cm ² , hardness 207 HB;

- purity according to non-metallic inclusions according to GOST 1778-70:

Type of inclusion Grade point average Maximum score sulfides 2,3 2,5 undeformed silicates 2.0 3.0 point oxides 0 0 lower oxides 2,5 3.0 plastic silicates 0 0 brittle silicates 1,0 1,0

From the results of the melting it follows that the obtained long products are hot-rolled in bars, round, with a diameter of 210 mm, made of stainless steel, with a qualitative and quantitative composition as claimed, has mechanical properties that significantly exceed the mechanical properties of the rolled products according to the prototype, are not inferior in terms of macrostructure characteristics, have higher austenitic grain number, i.e. finer grain, and a low purity score for non-metallic inclusions.

Thus, the implementation of the claimed high-quality high-quality rolled products in round bars made of steel with the declared qualitative and quantitative composition makes it possible to obtain high-quality long-rolled products in bars, round, with a diameter of 210 mm, not inferior to the known, from 30XMA steel - high-quality structural alloyed steel according to GOST 4543-71, according to the characteristics of the macrostructure, which has higher mechanical properties and allows its use in oil production for products, driver running with high mechanical loads, namely drilling compounds.

Claims (1)

Hot-rolled sections in bars, round, made of high-quality structural steel, made with specified parameters of mechanical properties, austenitic grain size, having a macrostructure with central porosity, point heterogeneity, segregation square of not more than 2 points for each type, shrinkage segregation of not more than 1 point, in the absence of a common spotted segregation, marginal spotted segregation, subcortical vesicles, intercrystalline cracks, characterized in that it is obtained from steel containing components following ratio, wt.%:
carbon 0.31-0.35 manganese 0.75-0.95 silicon 0.30-0.45 chromium 0.80-1.2 nickel 0.30-0.50 molybdenum 0.50-0.65 aluminum 0.015-0.040 iron and inevitable impurities rest,
moreover, steel contains inevitable impurities, wt.%: sulfur no more than 0.010, copper no more than 0.20, phosphorus no more than 0.015, nitrogen no more than 0.010, while the rolled product has a temporary resistance of at least 1050 N / mm ² , yield strength not less than 950 N / mm ² , elongation not less than 15%, relative narrowing not less than 55%, impact strength not less than 111 J / cm ² , hardness not more than 255 HB, austenitic grain size not more than 6 points, non-metallic inclusions on oxides and silicates no more than 4 points, non-deformable silicates no more than 4.5 points and sulfides no more than 4 points in, wherein the rolling heat treated by heating to a temperature of 670-690 °, exposure for 22 hours, cooling in the furnace to 600 ° and then cooled in still air to ambient temperature.