SU1544835A1 - Wear-resistant alloy - Google Patents

Abstract

The invention relates to the production of cast wear-resistant alloys, namely, the search for wear-resistant materials. The goal is to increase the hardness, machinability, flexural strength, wear resistance with hydro-abrasive wear. The alloy contains components in the following ratio, wt.%: Carbon 2,0-3,6

Chrome 12.0-24.0

nickel 0.1-0.7

molybdenum 0.1-0.7

phosphorus 0.03-0.50

sulfur 0.03-0.50

silicon 0.05-0.55

barium 0.02-0.05

iron - the rest. Introduction SI BA and increases to 43-49 HRC, wear 5.0-6.0 RLU, σ _mfd to 760-810 MPa. Cutting speed 15-16 m / min. 1 tab.

Description

The invention relates to the metallurgy of foundry alloys, namely to the search for wear-resistant materials.

The purpose of the invention is to increase the hardness, machinability, flexural strength, wear resistance during hydroabrasive wear.

The proposed alloy containing carbon, chromium, nickel, molybdenum, sulfur, phosphorus and iron, additionally contains silicon and barium in the following ratio, wt.%:

Carbon

Chromium

Nickel

Molybdenum

Sulfur

Phosphorus

Silicon

2.0-3.6 12.0-24.0 0.10-0.70 0.10-0.70 0.03-0.50 0.03-0.50 0.05-0.55

Barium 0.02-0.05

Iron Else

Carbon, taken in the range of 2.0–3.6%, provides for obtaining a sufficient amount of compact eutectic carbides in the alloy structure.

Reducing the carbon content below 2.0% results in a ledeburit structure and distribution of carbides along the grain boundaries, which significantly reduces the strength and wear resistance of the alloy.

When the carbon content is above 3.6%, the crack resistance of the alloy decreases, its strength decreases and the hardenability deteriorates, which leads to a loss of wear resistance of the castings. In addition, with an increase in the carbon content above 3.6%, large-block e-eutectic

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carbides that severely blunt the cutter during machining of the alloy, which leads to a deterioration in workability by cutting.

Chromium, taken in the range of 2.0–24.0%, ensures the production of high-wear resistant chromium carbides of the type (Cr, Fe) TC3 in the alloy structure. When chromium decreases below 12.0%, chromium atoms in the carbides of the type (Cr, Fe ) 7C with iron atoms, i.e. partial or complete replacement of high-resistant carbides (Cr, Fe) 7C3 with less wear-resistant carbides of the type (Fe, Cg) C.

Nickel taken in the range of 0.1-0.7% in combination with molybdenum ensures the hardenability of castings with a cross section of up to 150 mm. When the nickel content is below 0.1%, the hardenability of the alloy and, accordingly, the wear resistance deteriorate. When the nickel content is above 0E7%, the machinability is reduced. In addition, in the matrix of the normalized alloy, along with martensite, a certain amount of residual austenite is retained, which decreases its wear resistance.

Molybdenum in the range of 0, ensures high hardenability of the alloy prevents the decomposition of austenite in the pearlitic region. During heat treatment, when heated to the normalization temperature (1000 ° C), finely dispersed secondary molybdenum carbides are released, contributing to an increase in the wear resistance of the alloy.

When the content of molybdenum is less than 0.1%, the alloy reduces calcined heat and wear resistance. An increase in the molybdenum content of more than 0.7% does not lead to a further increase in wear resistance and therefore is irrational,

Sulfur contributes to the formation of iron sulphides, which are located along the grain boundaries around compact chromium carbides and play the role of a lubricant in the machining of parts on machine tools. When the sulfur content is below 0.03%, the alloy contains an insignificant amount of iron sulphides and the machinability deteriorates. Increase

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five

The reduction of sulfur content above 0.5% does not lead to a further improvement of machinability, reduces the strength of the alloy.

Phosphorus in the range of 0, 5% contributes to an increase in hardness and wear resistance due to the formation of a phosphide eutectic. When the phosphorus content is less than 0.03%, the increase in hardness is not observed due to the absence of phosphide eutectic. An increase in the phosphorus content of more than 0 to 5% leads to an increase in the brittleness of the alloy.

The introduction of silicon in the alloy in the range of 0.05-0.55% increases the hardness and wear resistance of the alloy. When the silicon content is above 0S55%, the temperature of eutectic crystallization increases, the range of eutectic transformation increases, which prevents overcooling, and the hardenability of the alloy decreases. The silicon content below 0.05% increases the number of scattered pores and, consequently, decreases the wear resistance of the alloy.

The introduction of barium into the alloy makes it possible to grind carbides, give them a compact form, and contributes to their uniform distribution in the matrix.

Such a form of carbides and their distribution in the matrix according to the Charpy principle leads to an increase in wear resistance to a decrease in internal stresses and an increase in the strength of the alloy. Due to the grinding of large block acute carbides, the machinability of the alloy due to the less intense blunting of the cutter is significantly improved.

When the barium content is below 0.02%, the carbides do not improve slightly, and no effect of improved properties is observed. When the barium content is higher than 0.05%, a dendritic structure is formed in the alloy, which leads to a deterioration of wear resistance and machinability.

The table shows the chemical composition of the alloys and their properties.

71544835 ch8

Ф о м м1 у л and inventions silicon and barium at the next

. the ratio of components, wt.%:

Wear-resistant alloy containing. Carbon 2.0-3.6

carbon, chromium, nickel, molybdenum, phos-Chromium 12.0-24.0

odds, sulfur, iron, distinguish-Nickel-0.1-0.7

| Ti and with the fact that, with the aim of higher-molybdenum0,1-0,7

Neither the hardness, the machinability of the cut-phosphorus 0.03-0.5

| shem, flexural strength, sulfur 0.03-0.5

Wear resistance1 with hydro-abrasive JQ Silicon 0.05-0.55

Wear, it additionally contains Barium 0.02-0.05

IronErest

Claims (1)

Claim Wear-resistant alloy containing carbon, chromium, nickel, molybdenum, phosphorus, sulfur, iron, characterized in that, in order to increase hardness, machinability, tensile strength, bending, Wear resistance · when waterjet Wear, it additionally contains silicon and barium at the following ratio of components, wt.%: Carbon 2.0-3.6 from Chromium 12.0-24.0 5 Nickel 0.1-0.7 Molybdenum 0.1-0.7 Phosphorus 0.03-0.5 Sulfur 0.03-0.5 10 Silicon 0.05-0.55 Barium 0,02-0,05 Jelly zo Rest