SU1705391A1 - Alloying additive for cast iron - Google Patents

Abstract

This invention relates to ligat-. frames for wear-resistant cast iron. In order to increase the microhardness and operational properties of cast iron, it additionally contains cerium, ferroboron carbonitrides, vanadium nitrides and titanium carbides in the following ratio of components, masD: copper 12-15; aluminum 6-8; carbon 0.2-1.0; cerium 6-11; ferroboron carbonitrides 10-15; vanadium nitrides 22-27; titanium carbides 7-12; phosphorus 5-U; iron else. The bucket treatment with the proposed neuutectoid cast iron ligature yields Gft 875-962 MPa, g 338-3 6 MPa, "hardness 5760-5995 MPa, while the wear resistance increases by more than kO%, and the service resistance is 1530-1635 h. 2 tab. 3 ate

Description

H3o6pefeHne relates to the field of foundry, in particular to master alloys for wear-resistant and high-strength cast irons with enhanced microhardness characteristics, mechanical properties and modulus of elasticity.

Known ligature, containing, wt.%:

Silicon30-70 Vanadium -20 Magnesium 3-20 Calcium 3-20 Titanium 0.5-U Chromium 0.5-Yu Iron Else A high content of carbide-forming elements (vanadium, manganese, chromium, titanium, magnesium) causes heterogeneity of the structure and occurrences

in the structure of the metal base of the carbides of these metals and free cementite, which reduces the homogeneity of the structure, crack resistance and the elastic modulus of cast iron, for which a known ligature is used.

Known ligature, containing, in May.%:

Chromium 0-50 Nickel 20-30 Silicon 6-10 Nitrogen 1-4 Manganese 3-6 Carbon 0.05-0, Titanium 2-6 Cerium 0.2-100 Iron Rest This ligature has insufficient micro-doping capacity and

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ABOUT

ate

with so

317 does not provide a significant improvement in the properties of iron castings obtained with its use.

The closest in technological essence and the achieved effect to the proposed is a ligature of the following composition, wt.%:

Copper30-5 Aluminum 20-30 Phosphorus 5-U Carbon 0.2- Iron Else Cast iron micro-doping with known ligature is carried out at 13 0-1 W / ° C by immersing the ligature on the bottom of the ladle as 1% of the melt mass. This provides an increase in temporal resistance of 30 MPa and solid

ti on 25 HB. The microhardness of the modified-2o shrinks the structure, increases the solid

cast iron 900-5780 MPa.

However, the known ligature does not provide a significant increase in the performance properties of cast iron.

The purpose of the invention is to increase the microhardness and performance properties of cast iron.

This goal is achieved by the fact that the master alloy for cast iron, containing copper, aluminum, phosphorus, carbon and iron, additionally contains cerium, titanium carbides, ferroboron carbonitrides, vanadium nitrides in the following ratio of components, mass: Copper 12-15 Aluminum 6-8 Carbon 0.2-1.0 Cerium 6-11 Ferroboron carbonitrides1 10-15 Vanadium nitrides 22-27 Titanium carbides 7-12 Phosphorus 5-U Iron Remaining Additional addition of 5 ferroboron carbonitrides to the composition provides increased strength, microhardness .and performance properties of cast iron in the mold Kah, corrosion resistance and strength properties izmel- chenie structure that provides a significant increase in stability and durability. When the concentration of ferroboron carbonitrides is up to 10 wt.%, The hardness, stability of the structure, technological properties and erosion resistance are insufficient, and with an increase in the content of more than 15 wt. reduced bend strength40

55

durability and erosion resistance, but their concentration is more than 12 wt.%, the homogeneity of the structure, plastic, technological and operational properties decrease. When the concentration of titanium carbides is less than 7 wt.%, The micro hardness, the limit of bending endurance and operational durability are insufficient.

Phosphorus in the composition of the alloy provides an increase in hardness, microhardness, wear resistance and operational properties. When the concentration of phosphorus is up to 5 mPh, the hardness, microhardness, wear resistance are insufficient, and at a concentration of more than 10 wt. 3; the uniformity of the structure decreases, the number of shrink holes increases, the microhardness and wear resistance decrease.

i

Carbon and aluminum render gras

the fitment effect reduces hardness, wear resistance and technological properties. Therefore, their concentration is limited, respectively, by the limits of 0.2–1.0 masD and 6–8 wt.1. In such an x-finish, aluminum and carbon have a deoxidizing and modifying effect without significantly reducing erosion resistance and exploitation properties.

Vanadium nitrides were additionally introduced in the amount of 22–27 May% with a decrease in the concentration of di to 12–15 May / -., Which contributes to an increase in the technological properties, the formation of austenite and c-perlite perlite, and an increase in cc of P1dmi-nioi. ER

five

free impact strength, plastic properties and operational durability.

Cerium modifies the structure, lowers the thermodynamic activity of carbon, increases the degree of spiroidization of graphite and non-metallic inclusions, which increases the technological, mechanical properties and operational properties. Its modifying and stabilizing effect begins to manifest itself with a content of 6.0 masD, but with an increase in its concentration of more than 11% by mass, the waste and the content of nonmetallic inclusions at the grain boundaries and lowering of microtransference are increased. Technological and erosion properties.

Titanium carbides perlite and from5

five

0

five

Density and erosion resistance, but at a concentration of more than 12 wt.%, the homogeneity of the structure, plastic, technological and operational properties decrease. When the concentration of titanium carbides is less than 7 wt.%, Microhardness, bending endurance and operational durability are insufficient.

Phosphorus in the composition of the ligature provides increased hardness, microhardness, wear resistance and performance properties. When the concentration of phosphorus is up to 5 mPd, the hardness, microhardness, wear resistance is insufficient, and at a concentration of more than 10 wt. 3; structure homogeneity decreases, the number of shrink holes increases, microhardness and wear resistance decrease.

i

Carbon and aluminum have a graphitizing effect, reduce hardness, wear resistance and technological properties. Therefore, their concentration is limited, respectively, by the limits of 0.2-1.0 masD and 6-8 mas.1. With such a concentration x, aluminum and carbon exert a deoxidizing and modifying effect without significantly reducing erosion resistance and performance properties.

Vanadium nitrides were additionally introduced in the amount of 22–27 May% with a decrease in the copper concentration to 12–15 May / -., Which contributes to an increase in the technological properties, the formation of austenite and 3-fold perlite, and an increase in cc of P1dmi-nioi. Erosion and operational durability, Austenitic-forming and whitening effect of vanadium nitrides and increasing hardness and erosion resistance begins to develop at a concentration of 22%, and with an increase in their content of more than 21%, the stability of the structure, erosion and operational durability of cast iron in castings decreases, technological deterioration properties.

Example. Experimental melts of master alloys were carried out in induction furnaces with crucibles with a capacity of 150 kg using ferroalloys, steel scrap, ferroboron carbonitrides, electrolytic copper, vanadium nitrides, cerium metal CeM-2, carbides, titanium. First, steel scrap, phosphorus and copper are melted in an induction furnace, the melt is overheated to 1350 ° C, then ferroboron carbonitrides and vanadium nitrides are introduced. After holding the melt for 2-3 min, aluminum was introduced into it, and before being released into various ladles, cerium metal. Casting is performed at ± 10 ° C in dry casting molds to obtain flat tiles with a thickness of 15-16 mm.

The ligature in crushed form is introduced into the dispensing buckets at a melt temperature of 1NO-50 ° C in cast iron containing, wt. $: Carbon 2.53; silicon 0.53; manganese 1,2; chromium 0.30; nickel 0.8; sulfur 0.02; phosphorus 0.06; calcium 0.01 and iron - the rest. The ligature is introduced in the amount of 0.7 masd from the amount of the melt.

In tab. 1 shows the chemical compositions of ligatures experienced bottoms.

The impact strength test was carried out on specimens with an UNO size of 55 mm with a c-shaped notch. This value should be at least 130 kJ / m2 (1.3 kgf.m / cm2).

The chemical composition of cast iron, the residual content of silicon nitrides and, accordingly, their degree of assimilation are determined by the method of quantitative differential chemical analysis of steels and alloys containing oxides and nitrides. The quality control of the modified Juugun is determined by checking the microstructure on the process samples and blanks for the samples. The stability of the modification process is expressed in% of the total volume of the samples and samples examined and represents the number of samples and samples that, according to the characteristics of the structure, corresponded to the technical conditions.

In tab. 2 shows the mechanical and operational properties of micro-alloyed iron, treated with master alloys of known and proposed compositions.

Wear resistance is determined on samples of 10 mm according to the test method for impact through an abrasive belt paired with samples of steel 5L after quenching it with water and tempering at 200 ° C, and testing for corrosion fatigue on cylindrical samples of Ush on the basis of 107 cycles at cyclic loading. Microhardness is determined on a PMT-3 microhardness meter. The study of strength properties is determined on cylindrical samples of 10 mm.

As can be seen from the table. 2, the proposed ligature provides higher operating and mechanical properties than is known.

(

formula of invention

The ligature for cast iron, containing copper, aluminum, phosphorus, carbon and iron, is characterized in that, in order to increase the microhardness of the performance properties of cast iron, it additionally contains cerium, ferroboron carbonitrides, vanadium nitrides and titanium carbides in the following ratio of components, wt. :

five

0

Copper

Aluminum

Carbon

Phosphorus

Cerium

Carbonitrides

ferroboro

Vanadium nitrides

Titanium carbide

Iron

12-15

6-8

0.2-1.0

5-U

6-11

10-15 22-27

7-12 Else

Table

Temporary resistance, MPa Endurance limit at bending, MPa Wear resistance, mm

Microhardness, MPa

Increasing the limit of corrosion fatigue, MPa Operational resistance, h

table 2

962580810581

3U5296317285

0, 0680.0550.075

5886523552555015

165110116, 80

161811811 21167

Claims (1)

Claim Ligature for cast iron, containing copper, aluminum, phosphorus, carbon and iron, characterized in that, in order to increase the microhardness of the operational properties of cast iron, it additionally contains cerium, ferroboron carbonitrides, vanadium nitrides and titanium carbides in the following ratio of components, wt.%: Copper 12-15 Aluminum 6-8 Carbon 0.2-1.0 Phosphorus 5th Cerium 6-11 Carbonitrides ferroboron 10-15 Vanadium Nitrides 22-27 Titanium carbides 7-12 Iron Rest Ί Table 1 Ligature The content of components (iron rest), wt.% Copper Aluminum Phosphorus Vanadium Nitrides Ferroboron Carbonitrides Titanium carbides Carbon Ceri 1 12 6 5 22 10 7 0.2 6 2 thirteen 7 8 25 12 eleven about 9 3 fifteen 8 10 27 fifteen 12 1,0 eleven 4 10 5 12 21 9 6 0.1 5 5 16 7 3 28 16 thirteen 1,1 12 6 (conv.) 35 9 7 - - - 0.3 - 1 table 2 Indicators Samples of ligatures 1 2 3 4 ^ 5 I6 (Izv. Temporary Resistance phenomenon, MPa 875 920 962 580 810 581 Bending endurance, MPa 338 346 345 296 317 285 Wear resistance mm 0,048 0,041 0,043 0,068 0,055 0,075 Microhardness, MPa 5760 5995 5886 5235 5255 5015 Increasing the limit of corrosion fatigue, MPa 130 168 165 110 116, 80 Operational Resistance, h 1530 1635 1618 1181 1442 1167