RU2033458C1 - Cast iron - Google Patents

Abstract

FIELD: metallurgy. SUBSTANCE: cast iron containing carbon, silicon, manganese, phosphorus, rare-earth elements, magnesium, alkaline-earth elements, chrome and iron has additionally aluminium and nickel. Components of cast iron were taken at the following ratio, wt.-%: carbon 2.0-3.6; silicon 2.5-3.5; manganese 0.1-1.5; phosphorus 3.0-3.5; rare-earth elements 0.01-0.03; alkaline-earth elements 0.001-0.035; magnesium 0.02-0.06; chrome 0.04-0.5; aluminium 0.1-0.5; nickel 0.01-1.1, and iron - the rest. EFFECT: enhanced quality of cast iron. 1 tbl

Description

 The invention relates to ferrous metallurgy, and in particular to compositions of cast irons that are used in the manufacture of brake pads.

 Currently, one of the most common materials in the production of railway brake pads is cast iron with a high phosphorus content, which provides good performance during wear castings.

Known cast iron [1] of the following composition, wt. Carbon 2.0-3.6 Silicon 0.5-2.5 Manganese 0.4-1.5 Titanium 0.08-0.2 Vanadium 0.05-0.2 Cerium 0.002-0.02 Phosphorus 1.0 -4.0 Iron Else
The disadvantages of this cast iron are insufficiently high wear resistance and coefficient of friction during friction in the field of high loads, which is associated with low resistance to destruction of this cast iron under the action of separation forces.

The closest in technical essence and the achieved result to the claimed composition of cast iron is cast iron [2] containing, by weight. Carbon 2.0-3.6 Silicon 1.8-3.5 Manganese 0.3-0.8 Phosphorus 1.0-3.5 Rare earth elements 0.005-0.05 Magnesium 0.02-0.06
Alkaline earth
grinding elements 0.001-0.035 Vanadium 0.02-0.3 Chromium 0.04-0.3 Iron Else
The disadvantages of this cast iron are insufficiently high coefficient of friction and its resistance to wear processes in severe friction conditions.

 The aim of the invention is to increase the coefficient of friction and reduce wear at a pressure in the friction system of 8 MPa.

This is achieved by the fact that cast iron containing carbon, silicon, manganese, phosphorus, rare earth elements, magnesium, alkaline earth elements, chromium and iron, according to the invention additionally contains aluminum and nickel in the following ratio, wt. Carbon 2.0-3.6 Silicon 2.5-3.5 Manganese 0.1-1.5 Phosphorus 3.0-3.5 REE 0.010-0.03 SCHE 0.001-0.035 Magnesium 0.02-0.06 Chrome 0.04-0.5 Aluminum 0.1-0.5 Nickel 0.01-1.1 Iron Else
The content of the components in the proposed cast iron is selected based on the following considerations. Studies of the influence of the atomic and electronic structures of metals on frictional properties show that one of the ways to increase the friction coefficient is to increase the strength of cohesive bonds. This can be achieved by increasing the covalent component in interatomic bonds, which, in particular, is achieved by increasing the amount of phosphides, silicides, and aluminides in the structure. It was also experimentally established that a decrease in the friction coefficient occurs due to an increase in the amount of cementite component in the structure of cast iron. Based on this, in the proposed cast iron, the claimed amount of silicon, phosphorus, and introduced aluminum. The presence in the cast iron of aluminum in the claimed amount, together with other components, ensures the isolation in its structure of a triple fine-grained phosphide eutectic and ferrite-pearlite metal base, which increases the friction coefficient of cast iron compared to the prototype.

 It is known that the intensity of the wear processes of cast irons during friction in the field of high loads largely depends not only on their initial structure, but primarily on the "secondary" structures formed in the surface layers that are the result of quenching and tempering processes. The introduction of the proposed composition of cast iron aluminum and nickel, distributed mainly in the metal base, promotes the formation of a metastable austenitic-martensitic-carbide structure in the surface layers of castings in contrast to the predominantly austenitic structure formed by friction, prototype cast iron. With a higher wear resistance, the austenitic-martensitic carbide structure provides reduced wear at high loads. When the content of the proposed cast iron of aluminum and nickel is lower than the declared limits, an increase in the coefficient of friction and a decrease in wear under friction at a pressure in the friction system of 8 MPa are not provided, since there is no effect on the nature of the formation of secondary structures during friction. When the content of these elements is higher than the proposed upper limit, the shape of graphite inclusions deteriorates, which, along with the spherical shape, partially stand out in the plate form, which reduces the protective effect of secondary structures during friction and increases wear in the field of high loads.

 A comparative analysis of the proposed technical solution with the prototype showed that this composition of cast iron differs from the known introduction of new components, namely aluminum and nickel. Thus, the claimed technical solution meets the criterion of "novelty."

 In the process of researching the claimed technical solution for scientific, technical and patent literature, no sources were identified that contained in the aggregate the features that distinguish this technical solution from the prototype.

 It is known the introduction of aluminum in the composition of cast iron [3], which provided an increase in its strength and wear resistance.

 It is also known that nickel is introduced into the composition of cast iron [4], which, together with other components of cast iron, made it possible to increase heat resistance, ductility, and performance properties.

 However, the introduction of nickel and aluminum in the composition of cast iron in combination with its other components does not provide the properties that they exhibit in the claimed solution, namely, an increase in the friction coefficient and reduced wear at a pressure in the friction system of 8 MPa.

 Thus, this feature exhibits a new previously unknown property, which allows us to conclude that the claimed technical solution meets the criterion of "significant differences".

 PRI me R. To analyze the impact of the proposed composition of cast iron on frictional properties, cast irons of the claimed composition and prototype composition were smelted, presented in the table. Smelting was carried out in 50 kg of induction furnace. The initial chemical composition of cast iron was as follows, wt. 1.9-3.7 C; 1.2-1.5Si; 0.05-1.6 Mn; 2.2-3.6 P; 0.03-0.6 Cr; 0.09-0.6 Al; 0.01-1.2 Ni; Fe the rest. When casting iron from the furnace to the ladle to obtain compact forms of graphite, it was processed using the FSM-5 complex modifier (TU 14-5-134-86). Samples prepared from these cast irons were tested for friction and wear according to the disk block scheme at the SMTs-2 installation at a pressure in the friction system of 8 MPa, which ensured the formation of secondary structures in the surface layers. Samples in the form of blocks made of heat-treated steel U8 with a hardness of 280 HB were used as a counterbody.

 As the measurements showed, when the content of cast iron components is on the lower and upper limits (samples N 2 and 3), an increase in the friction coefficient and a decrease in wear in the area of increased load are provided compared to the prototype. When the content of elements below the lower and above the upper level there is a sharp decrease in the coefficient of friction and increase the amount of wear (samples N 4 and 5).

The use of the claimed invention improves the operational properties of castings working in friction friction units,
reduce braking distance;
increase the life of castings.

Claims (1)

 CAST IRON containing carbon, silicon, manganese, phosphorus, rare earth elements, alkaline earth elements, magnesium, chromium and iron, characterized in that, in order to increase the friction coefficient and reduce wear at a pressure in the friction system of 8 MPa, it additionally contains aluminum and nickel in the following ratio of components, wt. Carbon 2.0 3.6
Silicon 2.5 3.5
Manganese 0.1 1.5
Phosphorus 3.0 3.5
Rare earth elements 0.01 0.03
Alkaline earth elements 0.001 0.035
Magnesium 0.02 0.06
Chrome 0.04 0.5
Aluminum 0.1 0.5
Nickel 0.01 1.1
Iron Else

Images