SU1749294A1 - High strength cast iron - Google Patents

Description

Additional introduction of antimony is due to the fact that it has the effect of grinding and inverting the structure, has a micro-effect, increases the stability of the structure under thermal shock conditions and its thermal and operational stability, which provides a significant increase in the resistance of high-strength cast iron to thermal shock. With an increase in its concentration of more than 0.06 wt.%, The number of lattice defects, metal base, non-metallic inclusions at grain boundaries increases, the shape factor of graphite inclusions worsens, thermal stresses increase, which reduces technological plasticity, crack resistance and resistance to thermal shock. The lower limit of the concentration of antimony (0.02 wt.%) Is due to its insufficient microalloying effect on the structure and the low operating properties of cast iron under the conditions of thermal shock and abrasion,

Additional introduction of boron is due to its modifying properties, improving the morphology of the structure, increasing the elastic-plastic properties, thermal stability, which contributes to an increase in the resistance of the pig iron to thermal shocks. When the boron concentration is up to 0.002 wt.%, The modifying effect and the increase in resistance to thermal shocks are insufficient, and at a concentration of more than 0.005 wt.%, The number of non-metallic inclusions at the grain boundaries increases, the elastic-plastic properties, resistance to thermal shocks and operational properties decrease.

Titanium increases the stability of the structure, contributes to the grinding and hardening of the matrix, cleans the grain boundaries, reduces the contamination of cast iron with nonmetallic inclusions, serves as a microalloying additive, improves the uniformity of the structure, thermal stability, performance and plastic properties. At a concentration of up to 0.02 wt.%, The micro-doping effect is insufficient, and with an increase in its content of more than 0.07 wt.%, The content of nonmetallic inclusions and heterogeneity of the structure increase, the technological plasticity, dynamic strength, and operational properties decrease under the conditions of tel.

Nitrogen ® amount of 0.04-0.11 wt.% Crushes the structure, forming nitrides, which serve as additional centers of graphitmeation, contributes to

resistance to tearing, wear resistance, crack resistance, technological and operational properties. When the nitrogen concentration is up to 0.04 wt.%, Its effect on

dispersion of structure, plasticity, technological and operational properties are not enough, and with an increase in its concentration of more than 0.11 wt.%, the content of non-metallic inclusions increases by

0 grain boundaries, which reduces the crack resistance, structural stability, technological and operational properties.

Bismuth is introduced as a bleaching component in the amount of 0.002-0.004

5 wt.%, Crushing the structure of the cast and annealed metal, increasing the stability of mechanical properties and contributing to an increase in endurance and impact-fatigue strength under conditions

0 alternating loads and plastic properties. The lower concentration of bismuth is taken as the content (0.002 wt.%), Which prevents the formation of free graphite in the cast metal, and the upper limit of the concentration is limited to 0.004 wt.%, Above which the contamination of the grain boundaries and the brittleness of the iron increase, is significantly lengthened. annealing cycle and reduced ductility, dynamic

0 strength and performance properties after low temperature isothermal aging.

Boundary parameters of carbon content (2.7-3.1 wt.%) And silicon (2.2-2.6

5 wt.%) Were determined based on the practice of producing high-strength cast irons with enhanced plastic properties, wear resistance and thermal stability. At a carbon concentration of more than 3.1

0 wt.% And silicon more than 2.6 wt.%, Crack resistance is reduced. impact viscosity and other mechanical and operational properties of cast iron, and at carbon concentrations up to 2.7 wt.% and silicon up to 2.2 wt.%

5, thermal stresses increase, crack resistance, thermal resistance, impact strength and other plastic properties in castings are reduced, which reduces the operational resistance of cast iron under heat exchange conditions when heated to 900 ° C.

Vanadium is introduced as an effective microalloying and hardening component that enhances the effect of grinding the matrix and graphite inclusions, providing

5 homogeneity of structure and increase of thermal and operational stability and elastic-plastic properties and their stability. The upper limit of the vanadium concentration (0.8 wt.%) Is due to increased chilling, a decrease in the technological plasticity of cast iron and an increase in the tendency to cracks with its higher content, which reduces the operational and elastic-plastic properties. With decreasing vanadium concentration of less than 0.2 wt.%, The structure is enlarged and the dynamic strength, yield strength, thermal and operational resistance decrease.

The content of alloying additives (manganese is 0.2-0.7 wt.%, Molybdenum is 1.2-1.8 wt.%, Nickel is 0.4-0.8 wt.%, Chromium is 0.02- 0.06 wt. %) due to a significant increase in thermal resistance, technological plasticity and strength, limited to the limits below which impact strength, heat resistance, technological plasticity and strength properties are insufficient, and above which thermal resistance increases and thermal resistance decreases, toughness and toughness performance properties.

The introduction of cerium in the amount of 0.02-0.06 wt.%, Tin 0.002-0.01 wt.%, Calcium 0.002-0.015 wt.% And magnesium 0.03-0.07 wt.% Due to their high modifying efficiency and surface activity , which in these quantities provide cleaning of grain boundaries, increase of plastic properties, crack resistance, resistance under heat exchange conditions and technological plasticity. Their content is due to the limits that provide dispersion and homogeneous structures in castings, spherical graphite in cast iron and the necessary operational and mechanical properties. as well as the stability of the pearlite structure after heat treatment and during operation. As their concentration increases above the upper limits, the operational properties decrease and their waste increases.

The introduction of aluminum in the amount of 0.02–0.07 wt.% Deadens, micro-alloyes the melt, crushes the structure and contributes to the improvement of thermal stability and fracture toughness while maintaining the strength properties. A low percentage of concentration (0.02 wt.%) Is taken from the content, from which its effect on the structure and properties of cast iron begins to affect, but with an increase in the concentration of more than 0.07 wt.%, Plastic properties decrease.

The smelting of cast irons is carried out in induction furnaces using cast iron as the charge materials. half of nickel, iron and steel scrap, ferrovanadium, ferromolybdenum, manganese silicate, ferrotitanium, Cy2 antimony, ferroboron, ferrosilicon and other ferroalloys. The microalloying of cast irons with copper, ferrovanadium FVd2, ferrotitanium with silicon manganese CMN17H is carried out in an electric furnace at the end of melting at 1500–1520 ° С, and

silicocalcium modification Ci, 30. ferrocerium (TU 1243-75). ferrobor FV17, bismuth Bi2, tin 02, magnesium alloys - directly in the dispensing casting buckets.

In tab. 1 shows the chemical composition of the cast iron experienced bottoms. The chemical composition of the cast irons is checked according to GOST 22536-0-77. GOST 22536.13-77, and the residual nitrogen content, the degree of absorption is determined by the method of quantitative differentiated chemical analysis of alloys.

Tests have shown that the proposed cast iron can be used for the manufacture of cast parts of increased

durability, wear resistance and operational durability.

The operational durability is determined by the durability of the metal molds when casting copper-nickel alloys into them.

In tab. 2 shows data on mechanical and operational properties. Mechanical properties and thermal stability are determined on standard specimens cut from castings after heat treatment, including isothermal holding at 400-420 ° C.

Claims (1)

Claims of High Strength Cast Iron Containing Carbon, Silicon, Manganese, Nickel, Chromium, Copper, Calcium, Magnesium, Vanadium, Aluminum, Molybdenum, Tin and Iron, characterized in that, in order to increase the operational durability under heat conditions, it additionally contains antimony, titanium, boron, cerium, nitrogen and bismuth in the following ratio of components, wt,%: carbon - 2.7-3.1: silicon - 2.2-2.6: manganese - 0.2-0.7 : Nickel - 0.4-0.8; chromium 0.02-0.06: vanadium - 0.2-0.8; aluminum - 0.02-0.07; molybdenum 1.2-1.8; antimony - 0.02-0.06: magnesium 0.03-0.07; tin 0.002-0.01; copper — 0.8–1.6; Calcium - 0.002-0.015; boron - 0.002-0.005: cerium 0.02-0.06; bismuth 0.002-0.004: nitrogen - 0.04-0.11: titanium - 0.02-0.07: iron - the rest. table 2