RU2062813C1 - Abrasion-resistant material - Google Patents

Abstract

FIELD: metallurgy. SUBSTANCE: proposed material contains (mass %): titanium carbide 10-60, nickel 4-15, carbon 0.2-1.5, cobalt 1-6 and ferrum the rest. EFFECT: improves quality of desired material. 1 tbl

Description

 The alleged invention relates to metallurgy, in particular to materials with high resistance to abrasion.

 A known composition made by casting from corrosion-resistant metals and containing, by weight. carbon 0.5-3.0, chromium 13-30, molybdenum 0.7-6.0, manganese 0.1-2.0, nickel 0.5-3.0, as well as chromium or titanium carbides 20-30 in the form of grains with a size of 8-10 microns, which significantly increase the service life of products obtained from the material (see, e.g., Switzerland No. 432535, class B 02 C 7/12, 1984; Japan No. 60-56054, class D 21 D 1/30, 1985).

The Defibrator company (Sweden) produces TD steel, superior in wear resistance to other known materials, which contains, by weight. carbon 1.7; chrome 16.5; nickel 2.2; molybdenum 0.7; titanium 1.7. Moreover, in the finished product, as a result of heat treatment, chromium and titanium are contained in the form of primary and secondary carbides (FeCr) ₃ C and TiC in the amount of 20% (see the report by VEINO Lampe “Steel grades for grinding disk segments”).

 A disadvantage of the known solutions is the difficulty of regulating the physicomechanical characteristics of materials. One of the methods for increasing the physicomechanical characteristics in steels is the introduction of carbides of refractory metals during the casting process, resulting in a mechanical mixture of two components in which carbides are an integral part. However, the distribution of carbides by weight of the metal is uneven and difficult to control, therefore, the structure of the obtained metal is heterogeneous and does not ensure the stability of the obtained properties, which leads to a decrease in the service life of the products and affects the quality of the mass.

 The closest set of features to the claimed is a wear-resistant material containing titanium carbide, iron, nickel, silicon and carbon in the following ratio, wt.

Iron 13.26-44.11
Nickel 2-15
Silicon 0.32-1.5
Carbon 0.09-0.35
Titanium carbide rest.

The disadvantage of this material is the complexity of its manufacture, in particular, the long grinding of the mixture with carbide balls (up to 72 hours), which can change the chemical composition of steel and, consequently, the structure of the binder after sintering, which makes it difficult to choose heat treatment modes. Preliminary sintering in hydrogen at a temperature of 650-700 ^o C for 30 minutes does not give the compacts sufficient strength. However, the relatively narrow range of variation in carbon content makes it difficult to choose the optimal sintering temperature.

 The inventive wear-resistant material containing iron, titanium carbide, nickel and carbon is characterized in that it additionally contains cobalt in the following ratio of components, wt.

Titanium Carbide 10-60
Nickel 4-5
Carbon 0.2-1.5
Cobalt 1-6
Iron rest
The proposed composition containing titanium carbide as a filler and other components as a binder, allows to increase the wear resistance of the material and simplify the technology for obtaining products from it.

 Introduction to the composition of the cobalt material taken in an amount of 1-6 wt. enhances the ductility of the binder, facilitates the flow of plastic deformation, ensures a uniform distribution of carbon atoms, helps to reduce residual austenite to such an extent that provides a significant increase in the level of wear resistance. With a decrease in the cobalt content in powder steel below 1.0 wt. the content of residual austenite increases after sintering of the composition (30-40%), which impairs wear resistance. In the case of cobalt content of more than 6.0 wt. steel becomes brittle, which also leads to a decrease in the wear resistance of the product, but due to the chipping of the binder and grains of titanium carbide.

 When the content in the material of Nickel more than 15 wt. the point of the onset of martensitic transformation decreases, the percentage of residual austenite increases, which leads to a deterioration in wear resistance, and rapid production of a binder. When the Nickel content is less than 4.0 wt. the binder viscosity decreases, brittleness increases, which helps to reduce wear resistance and deteriorate the quality of the resulting mass during grinding.

 The presence in the material of graphite in an amount of 0.2-1.5 wt. gives hardness to the binder.

 The proposed technical solution is characterized by the following examples of specific performance.

 The mixture was prepared using a colloidal graphite preparation of the S-1 OST grade 6-09-431-75, nickel powder of the carbonyl grade PNK-OT4 GOST 9722-79, cobalt powder PK-1 GOST 9721-79, and iron powder of the ПЖРВ 2.200.26 grade TU 14-1-38-82-85, titanium carbide powder TU 48 A3 USSR 14-81 with a particle size of 10-60 microns. With a decrease in the grain size of titanium carbide below 10 μm, the electric energy consumption for grinding increases, it becomes difficult to obtain the required degree of grinding, the mass begins to “burn” in the grinding zone. With an increase in the grain size of the filler over 60 μm, it begins to crumble, and wear resistance deteriorates.

The mixture was obtained by mechanical mixing of the components in a double cone mixer. Pressing of samples in the form of cylinders with a diameter of 15 mm and a height of 20 mm was carried out at a pressure of 400 MPa. The obtained samples were first sintered in an atmosphere of dried hydrogen with a dew point of 30 ^° C at a temperature of 800 ^° C for 1 h, and then in vacuum at a temperature of 1380-1470 ^° C for 30 minutes.

 For experimental verification of the claimed composition were prepared 32 types of samples with different ratios of components (see table). The compositions of the alloys and the results of their abrasion tests are presented in the table (examples 1-24 of the proposed composition; 25-30 alloys with an exorbitant content of binder components; 31-32 alloys with an exorbitant content of titanium carbide).

 Wear resistance (abrasive wear) was determined by the method of the company "Sunds Defibrator".

The tests were carried out under the following conditions:
disk rotation speed of 250 rpm;
sanding paper with an abrasive surface of silicon carbide with an average grain size of 79 microns;
the sample holder rotates at a frequency of 52 rpm in a direction opposite to the direction of rotation of the grinding disk;
the force on the sample is 9.1 g / mm ² ;
total test time 2 min, recording a decrease in sample mass every 30 s. TTT1 TTT2

Claims (1)

 Wear-resistant material containing iron, titanium carbide, nickel, cobalt and carbon, characterized in that it contains components in the following ratio, wt. Titanium Carbide 10-60
Nickel 4-15
Carbon 0.2-1.5
Cobalt 1-6
Iron Else

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