RU2505619C1 - Low-carbon alloy steel - Google Patents

Abstract

FIELD: metallurgy.

SUBSTANCE: steel contains the following component ratio, wt %: carbon 0.08 - 0.20, manganese 0.30 - 0.65, aluminium 0.02 - 0.09, vanadium 0.10 - 0.20, sulphur 0.026 -0.030, and iron is the rest. Total aluminium and vanadium content is 0.19 - 0.22 wt %.

EFFECT: enlarging the range of formed housings of artillery ammunition, improving manufacturability of ammunition in serial production and improving properties of their primary usage.

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Description

The invention relates to metallurgy, and more specifically, to low-carbon alloy steel for cold extrusion, from the bar stock of which a shell of a projectile is pressed onto which a copper lead belt is welded.

This technical field is characterized by mild steel for cold drawn welding wire according to patent RU 2148674 C1, C22C 38/50, C22C 38/38, B23K 35/30, 2000, which contains iron, carbon, manganese, nickel, titanium, aluminum, vanadium sulfur and phosphorus in the following ratio (wt.%):

carbon 0.04-0.06 manganese 1.1-1.5 nickel 1.7-1.9 titanium 0.05-0.12 aluminum no more than 0,04 vanadium no more than 0,03 sulfur no more than 0,006 phosphorus no more than 0,008 iron rest

A feature of the described steel is that the total content of nickel and manganese is 3.0-3.3 wt.% And the total content of sulfur and phosphorus does not exceed 0.013 wt.%.

The use of titanium in steel allows you to limit the growth of grain in the metal during the welding process. The titanium content of 0.05-0.12 wt.% Was established experimentally from the conditions for the formation of titanium carbides in the weld metal, corresponding to a stoichiometric ratio of the content of titanium and carbon fractions, ensuring grain size stability in the weld metal (weld).

A titanium content below 0.05 wt.% Does not allow to control grain growth, and a content above 0.12 wt.% Does not lead to further improvement of the metal structure.

The carbon content of not more than 0.06 wt.% Taken from the condition of increasing the cold resistance of welds.

The carbon content of not less than 0.04 wt.% Taken from the condition of ensuring the strength of the deposited material.

The sum of the mass fractions of nickel and manganese in the range of 3.0-3.3% with a nickel content of 1.7-1.9% and a manganese content of 1.1-1.5% was established experimentally from the condition of ensuring stability of strength properties, in particular, yield strength in the range of 500-570 N / mm ² .

To resist brittle fracture of welds at low temperatures, the phosphorus content is limited to not more than 0.008% with a total sulfur and phosphorus content of not more than 0.013%.

Steel is smelted in 100-ton arc furnaces using single-slag processes and up to 30% of molten iron in casting. The oxidized period begins at the end of the melting, which helps to obtain a low gas content in the metal.

Refined slag is induced in the ladle, under which metal is deoxidized and alloyed with simultaneous treatment with argon in a vacuum. In the process of casting into an ingot, the metal stream is protected by means of special devices and argon from secondary oxidation.

The described steel is characterized by high manufacturability in automatic welding under various types of fluxes.

A continuation of the noted advantages of this steel are its inherent disadvantages, which are expressed by its unsuitability as a structural material of the shells of artillery shells due to the low strength characteristics and durability of the press and cutting tools, poor adhesion with copper.

More advanced is low-carbon alloy bar steel grade 15FYUA according to GOST B.10230 for the manufacture of shells by cold extrusion, which is selected by the number of matching features and technical essence as the closest analogue of the proposed one, which contains iron, carbon, manganese, aluminum, vanadium and sulfur, in the following ratio of components (wt.%):

carbon 0.13-0.18 manganese 0.30-0.50 aluminum 0.02-0.07 vanadium 0.10-0.15 sulfur up to 0.025 iron rest

(see. Marochnik, Steels and alloys, V. G. Sorokin, M., Intermet Engineering, 2001, p. 10).

The specified steel, which is selected by technical essence and the number of matching features as the closest analogue of the proposed one, is used for the manufacture of small-caliber shells by multi-junction cold extrusion of a chamber for explosive equipment, the leading belt of which is formed by pressing a copper ring into a radial groove of a special profile.

When stamping a bar billet forming cold extrusion of the projectile chamber, concomitant steel hardening and hardening occurs, as a result of which a predetermined yield strength σ ₀₂ ≥65 kg / mm ² is achieved, which ensures normal operation of the projectile under dynamic loading in the bore.

The presence of aluminum in steel improves its manufacturability, since aluminum binds free nitrogen, preventing deformation aging of the case steel during press operations.

The presence of vanadium in the composition of the steel along with aluminum provides grain refinement for hardening during volumetric deformation of the stamped body.

A disadvantage of the known steel is the limited suitability for electric arc surfacing of the copper lead strip directly on the centering belt of the body due to local softening of the metal, as well as the abrasive effect on the cutting tool when shaping the outer profile of the shells due to the low sulfur content, the compounds of which serve as solid lubricant .

Moreover, sulfur in this steel is an impurity and may be completely absent, which limits the mass production of ammunition, on the bodies of which stamping a grid of riffles is formed, forming half-finished fragments. This ensures a given crushing of the shell into effective damaging elements, since the rolled sulfur inclusions serve as stress concentrators, increasing the number of fragments.

After pressing operations, mechanical cutting is carried out, accompanied by metal sticking to the cutting tool due to the low sulfur content in the steel.

The total content of aluminum and vanadium in the known steel of 0.17 wt.% Is not enough for a complete bond of nitrogen and oxygen, which reduces the quality of the deposited copper girdle on the shell of the projectile (there are pores in the volume of the leading girdle, which can cause it to break down during firing) and causes strain aging in press operations.

In addition, due to the limitation of the lower carbon content limit, known steel is not used for the manufacture of artillery grenades, the strength characteristics of the shells of which are not controlled (σ ₀₂ = 40-60 kg / mm ² , which is lower than that required for shell shells)

When using known steel for the manufacture of stamped grenade cases, the conditional yield strengths are obtained above the specified, which causes additional loads on the pressing tool.

Due to the limitation of the upper limit of the content in the manganese steel of 0.50 wt.%, When there is a minimum amount of carbon, the fragmentation of the munition shell occurs with conglomerates of fragments, which reduces the effectiveness of the damaging effect.

The technical problem to which the present invention is directed is to expand the range of products with semi-finished fragments made by cold extrusion of bar blanks from mild alloyed steel during electric arc welding of copper lead belt directly on the centering thickening of the body.

The required technical result is achieved by the fact that the known low-carbon alloy steel containing iron, carbon, manganese, aluminum, vanadium and sulfur, according to the invention, includes sulfur as an alloying component, and the total content of aluminum and vanadium is limited to a range of 0.19-0.22 wt.%, with the following content of components (wt.%):

carbon 0.08-0.20 manganese 0.30-0.65 aluminum 0.02-0.09 vanadium 0.10-0.20 sulfur 0.026-0.030 iron rest

Distinctive features of the proposed technical solution ensured the expansion of the range of stamped shells of artillery ammunition, the leading device of which is carried out by electric arc welding of copper filler wire directly to the centering thickening, which increases the manufacturability of the production of ammunition in serial production and improves the performance of their main purpose.

Advanced steel is additionally suitable for the manufacture of shells for artillery grenades, which do not have a limit on the strength characteristics, which allowed to expand the range of carbon content in it, reducing the minimum allowable lower limit to 0.08 wt.%.

Reducing the carbon content in steel provides a reduction in press tool loads.

When the carbon content in the steel is greater than 0.20 wt.%, The wear of the pressing tool is unacceptably increased.

The optimized carbon content in the proposed carbon steel of 0.08-0.20 wt.% Provides the specified strength of the stamped shells of artillery shells and additionally makes it possible to produce grenades for which an excess of strength is not required, therefore, a reduction in the loads on the stamping tool is achieved.

Thus, the steel according to the invention is universal.

When the manganese content in the steel is less than 0.25 wt.%, Incomplete metal deoxidation occurs when unbound oxygen forms non-metallic inclusions, which during stamping can cause destruction of the product.

The increase, compared with the prototype, the content of manganese steel in the upper range from 0.50 to 0.65 wt.% Improves the weldability of steel, improves the strength characteristics of the shells of ammunition and increases the durability of the pressing tool.

When the content of manganese in steel is more than 0.65 wt.%, Ferrite hardens, which creates an additional load on the pressing tool, reducing its resistance.

The experimentally tested range of 0.19-0.22 wt.% Of the total aluminum and vanadium content guaranteed ensures the adhesion of the deposited copper lead belt to the munition body due to improved adhesion of copper to steel in the common weld pool, not eliminating pore formation by metal interface.

The total content of aluminum and vanadium in the steel below 0.19 wt.% Is not enough to prevent pore formation during surfacing of the copper strip and to prevent strain aging.

When the aluminum content in the steel is less than 0.02 wt.%, Free nitrogen is not fully bound, which leads to deformation aging of the metal of the casings and the grain is not crushed enough, which reduces the strength characteristics of the steel.

Part of the aluminum in steel, passing into oxides, serves to grind grain, being the center of crystallization, which increases the strength of the metal, and part binds free nitrogen, preventing its deformation aging.

When the aluminum content in the steel is more than 0.09 wt.%, Many aluminum oxides (Al ₂ O ₃ ) are formed, which have high hardness and have an abrasive effect on the cutting tool reducing its resistance.

When the vanadium content in the steel is less than 0.10 wt.%, Free nitrogen and oxygen are not fully bound, which reduces the adhesion strength of copper to steel due to the presence of pores in the common weld pool.

In addition, the lack of vanadium steel causes strain aging in press operations.

The vanadium content in steel, compared with the prototype, is significantly increased so that excess carbides are formed, which provide crushing of the body along the boundaries of the ferrite matrix.

The content in the vanadium steel of more than 0.20 wt.% Does not create a noticeable improvement in the adhesion adhesion of copper of the driving belt to the body metal.

When the sulfur content in the steel is in the range of 0.026-0.030 wt.%, Sulfur compounds are formed in an amount that ensures, as a solid lubricant, the tool improves the machinability of the bodies by cutting, when forming the outer profile and applying a grid of corrugations that weaken the shell for oriented crushing on the damaging elements of the specified mass and dimensions parameters.

Consequently, each essential feature is necessary, and their combination in a stable relationship is sufficient to achieve a novelty of quality that is not inherent in the characteristics of disunity, that is, the technical task posed is not solved by the sum of the effects, but by a new super-effect of the sum of the attributes.

The proposed low-carbon alloy steel is technologically advanced in the preparation and processing into a body of a wide range of artillery ammunition, which at the same time have increased strength characteristics and improved designation, which makes it possible to recommend it for practical use.

For comparative technical tests, samples of the proposed steel were used, in which the components are contained within the optimized ranges, beyond and at the boundaries of the selected component content, are presented in table 1.

The chemical composition of the metal experimental swimming trunks Table 1 Ingredients The content of ingredients in steel samples, wt.% one 2 3 four 5 6 15FYAA Carbon 0.06 0.08 0.12 0.16 0.20 0.21 0.16 Manganese 0.25 0.30 0.50 0.60 0.65 0.70 0.30 Aluminum 0.01 0.02 0.04 0,07 0.09 0.10 0.04 Vanadium 0.08 0.10 0.12 0.18 0.20 0.22 0.12 Sulfur 0,025 0,026 0,027 0,028 0,030 0,031 0.010

The average values of the measured mechanical characteristics of the samples, indicators of manufacturability and the main purpose of the selected samples, compared with the standard steel 15FYUA, are summarized in Table 2.

Sample Test Results table 2 Indicators one 2 3 four 5 6 15FYAA Tensile strength σ _in kg / mm ² 68 70 73 77 81 81 77 Yield strength σ ₀₂ , kg / mm ² 60 65 68 69 72 73 68 Elongation δ,% 10 9 8 8 7 7 8 Tool life 1.07 1.06 1.05 1,04 1,08 1.09 1.00 Tool life 1.10 1,08 1.06 1.00 0.98 0.90 1.00 The number of effective fragments 0.95 1.06 1,08 1.00 1,02 1,03 1.00

An experimental verification of the proposed steel in the manufacture of a batch of cases of small-caliber artillery grenades and shells showed suitability for serial production according to the modes of technological operations and the durability of press and cutting tools, while ensuring a solid one-piece connection of the copper lead belt with the munition body, excluding its local softening during electric arc surfacing of the filler copper wire.

A comparative analysis of the proposed technical solution with identified analogues of the prior art, from which the invention does not explicitly follow for a specialist in artillery ammunition, showed that it is unknown, and given the possibility of industrial serial production of modernized steel on existing equipment, we can conclude that the criteria patentability.

Claims (1)

Mild alloyed steel containing iron, carbon, manganese, aluminum, vanadium and sulfur, characterized in that it contains components in the following ratio, wt.%:
carbon 0.08-0.20 manganese 0.30-0.65 aluminum 0.02-0.09 vanadium 0.10-0.20 sulfur 0.026-0.030 iron rest,
while the total content of aluminum and vanadium is limited to a range of 0.19-0.22 wt.%.