WO2016107517A1 - High wear-resistant alloy steel for railway frog and manufacturing method therefor - Google Patents

Abstract

A high-strength wear-resistant steel for railway frog and a manufacturing method therefor, wherein the composition of the wear-resistant steel is: 0.29%-0.45% of C, 0.20%-0.59% of Si, 0.90%-1.51% of Mn, P≤0.015％, S≤0.010％, 1.52%-1.79% of Cr, 1.01%-1.49% of Ni, 0.29%-0.59% of Mo, 0.02%-0.07% of Al, 0.025%-0.10% of Nb, 0.05％≤Nb+Al≤0.15％, [O]≤20 ppm, [N]≤100 ppm and [H]≤0.50 ppm, with the balance being iron and unavoidable impurities.

Description

High wear-resistant alloy steel for railway frog and manufacturing method thereof Technical field

The invention belongs to the field of alloy steel and a manufacturing method thereof, and relates to a high-performance alloy steel, in particular to a high wear-resistant alloy steel for railway frogs and a manufacturing method thereof.

Background technique

The high-speed heavy-duty railway has extremely severe operating conditions for the ballast equipment due to its large axle weight, high density and large traffic conditions, which makes the wear and damage of the forks and other parts of the ballast far greater than the same type of ordinary line. Turns. With the further development of rail transportation to heavy loads, active high manganese steel frogs have become increasingly difficult to meet their needs. For forks with poor service conditions (especially for the split core and wing rails), not only must they have sufficient hardness and strength, but also sufficient toughness to improve their wear resistance. At present, the technical requirements for the relevant indicators of commercial alloy steel frogs are as follows (see “Technical Conditions for Alloy Steel Axle Combination Bifurcation (Provisional)” in Document No. 230 (2005): R _m ≥1240MPa, α _KU (room _{^{temperature) ≥70J / cm 2, α KU}} (-40 ℃) ≥35J / cm 2, hardness 38 ~ 45HRC. A typical commercial frog is selected for testing, and its composition and mass percentage ratio: C 0.25, Si 2.08, Mn 1.69, P 0.008, S 0.002, Cr 1.40, Ni 0.30, Mo 0.28, Al 0.03, Nb 0.01, O 18 ppm, N 74 ppm, H 0.39 ppm, the balance being iron and unavoidable impurities. The mechanical properties were as follows: R _m was 1263 MPa, R _p0.2 was 1020 MPa, hardness was 39.5 HRC to 42.0 HRC, α _KU (room temperature) was 74 J/cm ² , and α _KU (-40 ° C) was 37 J/cm. ² .

To this end, in the past decade or more, both domestic and foreign countries have been trying to develop high wear-resistant alloy steel frogs that meet the requirements of high-speed heavy-duty railway transportation. For example, CN100449027C discloses a wear-resistant steel suitable for railway ballasts, which uses Si-Mn-Cr-Mo-based alloying elements and adds V and Ti refined grains, and the manufacturing process is improved to some extent by a deformation heat treatment process. The quality stability of the frog and the production cost are reduced, but its hardness and impact toughness are not very superior. CN1166804C discloses a super high-toughness weldable air-cooled Hongkang bainitic steel for railway frogs and a manufacturing method thereof, which adopts Mn and Si as main alloy elements, supplemented with elements such as Cr, Ni, Mo, and Ti, V and Nb are refined grain elements, and the ordinary smelting method is adopted for manufacturing. However, since Mn and Si are the main additive elements, segregation of Mn is inevitable in the smelting process, resulting in uneven cross-sectional performance. The stability of the intrinsic quality is poor, and at the same time, due to the large addition of Si, a large amount of oxidation of the surface of the workpiece during forging and heat treatment is caused, thereby wasting material and increasing processing cost.

Summary of the invention

The object of the present invention is to provide a high wear-resistant alloy steel for railway frogs, which is a high-strength, high-hardness, high-toughness wear-resistant steel, and is particularly suitable for high-speed heavy-duty railway frogs.

The object of the present invention is achieved by the following technical solutions:

According to one aspect of the invention, a high wear-resistant alloy steel for railway frogs, the components and their mass percentages are as follows: C 0.29% to 0.45%, Si 0.20% to 0.59%, Mn 0.90% to 1.51%, P ≤0.015%, S≤0.010%, Cr 1.52%～1.79%, Ni 1.01%～1.49%, Mo 0.29%～0.59%, Al 0.02%～0.07%, Nb 0.025%～0.10%, 0.05%≤Nb+Al ≤ 0.15%, [O] ≤ 20 ppm, [N] ≤ 100 ppm, [H] ≤ 0.50 ppm, and the balance is iron and unavoidable impurities.

According to another aspect of the present invention, a method for manufacturing a high wear-resistant alloy steel for a railway yoke includes the following steps: electric arc furnace smelting→ ladle furnace refining→vacuum furnace degassing→die casting→initial rolling Blank → forging type → dehydrogenation heat treatment → final heat treatment; wherein the forging type adopts free forging and die forging, and the final heat treatment includes controlled cooling after 0.1 ° C / s to 0.8 ° C / s after austenitizing, after cooling to room temperature Re-tempering.

The wear-resistant alloy steel of the present invention has a carbon content of 0.29% to 0.45% to ensure excellent hardness and strength properties of the alloy steel of the present invention, and has very high toughness and good weldability. The addition of alloying elements Mn, Cr, Ni, Mo and its suitable ratio can effectively improve the strength, hardness and toughness of the alloy steel, and ensure the uniformity of structure and performance of the entire part cross section. And consistency. The addition of alloying elements Al and Nb and their suitable ratio selection can effectively inhibit austenite grain growth during forging and heat treatment, refine grains and improve the strength, ductility and toughness of the alloy steel.

Compared with the prior art, the high wear-resistant alloy steel for railway frogs according to the present invention adopts the addition of C, Mn, Cr, Ni, Mo, Al, Nb and the appropriate ratio selection thereof, thereby effectively improving the resistance. Strength, hardness and toughness properties of steel.

The manufacturing method of the present invention adopts a system control method of smelting, forging and heat treatment, which can reduce segregation of alloying elements of steel ingots, and improve uniformity of cross-section performance and stability of intrinsic quality of forgings. The mechanical performance index of the high wear-resistant alloy steel for railway frogs of the present invention is as follows: R _m ≥ 1605 MPa, R _p0.2 ≥ ₁₃₀₀ MPa, hardness ≥ 48 HRC, α _KU (room temperature) ≥ 100 J/cm ² , α _KU (-40 ° C) ) ≥ 70J/cm ² . Compared with a typical commercial frog, the mechanical properties of the high wear-resistant alloy steel for the railway frog of the present invention have a significant increase.

In summary, the alloy steel of the present invention has high strength, high hardness and high toughness performance characteristics, and is particularly suitable for the demand of high speed heavy-duty railway frogs, and has the characteristics of high service life, easy manufacture, and easy assembly and use.

detailed description

The application provides the following technical solutions:

Technical Solution 1. A high wear-resistant alloy steel for railway frogs, characterized in that each component and its mass percentage are as follows: C 0.29% to 0.45%, Si 0.20% to 0.59%, Mn 0.90% to 1.51%, P ≤ 0.015%, S ≤ 0.010%, Cr 1.52% to 1.79%, Ni 1.01% to 1.49%, Mo 0.29% to 0.59%, Al 0.02% to 0.07%, Nb 0.025% to 0.10%, 0.05% ≤ Nb + Al ≤ 0.15%, [O] ≤ 20 ppm, [N] ≤ 100 ppm, [H] ≤ 0.50 ppm, and the balance is iron and unavoidable impurities.

Technical Solution 2. The high wear-resistant alloy steel according to the first aspect, wherein the mass percentage of C is 0.29% to 0.34% or 0.35% to 0.39% or 0.40% to 0.45%.

The high wear-resistant alloy steel according to claim 1 or 2, wherein the mass percentage of Mn is from 1.01% to 1.51%.

The high wear-resistant alloy steel according to any one of claims 1 to 3, wherein the mass percentage of Ni is from 1.01% to 1.31% or from 1.21% to 1.49%.

The high wear-resistant alloy steel according to any one of claims 1 to 4, wherein the mass percentage of Mo is 0.35% to 0.59% or 0.29% to 0.49%.

Technical Solution 6. The high wear-resistant alloy steel according to claim 1, wherein each component and its mass percentage are as follows: C 0.29% to 0.34%, Si 0.20% to 0.59%, and Mn 1.01% to 1.51%. , P ≤ 0.015%, S ≤ 0.010%, Cr 1.52% to 1.79%, Ni 1.21% to 1.49%, Mo 0.35% to 0.59%, Al 0.02% to 0.07%, Nb 0.025% to 0.10%, 0.05% ≤ Nb +Al ≤ 0.15%, [O] ≤ 20 ppm, [N] ≤ 100 ppm, [H] ≤ 0.50 ppm, and the balance is iron and unavoidable impurities.

The high wear-resistant alloy steel according to the first aspect, characterized in that each component and its mass percentage are as follows: C 0.35% to 0.39%, Si 0.20% to 0.59%, and Mn 0.90% to 1.51%. , P ≤ 0.015%, S ≤ 0.010%, Cr 1.52% to 1.79%, Ni 1.01% to 1.49%, Mo 0.29% to 0.59%, Al 0.02% to 0.07%, Nb 0.025% to 0.10%, 0.05% ≤ Nb +Al ≤ 0.15%, [O] ≤ 20 ppm, [N] ≤ 100 ppm, [H] ≤ 0.50 ppm, and the balance is iron and unavoidable impurities.

Technical Solution 8. The high wear-resistant alloy steel according to claim 1, wherein each component and its mass percentage are as follows: C 0.40% to 0.45%, Si 0.20% to 0.59%, and Mn 0.90% to 1.51%. , P ≤ 0.015%, S ≤ 0.010%, Cr 1.52% to 1.79%, Ni 1.01% to 1.31%, Mo 0.29% to 0.49%, Al 0.02% to 0.07%, Nb 0.025% to 0.10%, 0.05% ≤ Nb +Al ≤ 0.15%, [O] ≤ 20 ppm, [N] ≤ 100 ppm, [H] ≤ 0.50 ppm, and the balance is iron and unavoidable impurities.

The high wear-resistant alloy steel according to any one of claims 1 to 8, characterized in that the mechanical properties of the high wear-resistant alloy steel are as follows: R _m ≥1605 MPa, R _p0.2 ≥ 1300 MPa, hardness ≥ 48 HRC, α _KU (room temperature) ≥ 100 J/cm ² , α _KU (-40 ° C) ≥ 70 J/cm ² .

The method for producing a high wear-resistant alloy steel for railway frog according to any one of claims 1 to 9, characterized in that the manufacturing method comprises the following steps in sequence: electric arc furnace smelting → Ladle furnace refining→vacuum furnace degassing→die casting→initial rolling blanking→forging type→dehydrogenation heat treatment→final heat treatment; wherein the forging type adopts free forging and die forging, and the final heat treatment includes 0.1°C after austenitizing Control cooling after /s ~ 0.8 ° C / s, cool to room temperature and then tempered.

Item 11. The method for producing a high wear-resistant alloy steel according to claim 10, wherein the final heat treatment comprises austenitizing at 890 ° C to 980 ° C and then air cooling to room temperature, and the cooling rate is 0.3 ° C / s ~ 0.5 ° C / s; then tempering at 160 ° C ~ 550 ° C.

The method for producing a high wear-resistant alloy steel according to claim 10, wherein the final heat treatment comprises austenitizing at 890 ° C to 980 ° C, and then air cooling to room temperature, and the cooling rate is 0.5 ° C / s ~ 0.8 ° C / s; then tempering at 160 ° C ~ 550 ° C.

The method for producing a highly wear-resistant alloy steel according to any one of claims 10 to 12, wherein the tempering temperature is in the range of 300 ° C to 450 ° C.

The unavoidable impurities described in this application refer to impurities that cannot be completely smelted and removed in scrap steel or ore during smelting, such as trace elements such as As, Sn, Pb, Sb, Bi, etc. The content of these elements usually needs to be controlled. As ≤ 0.01%, Sn ≤ 0.01%, Pb ≤ 0.01%, Sb ≤ 0.01%, Bi ≤ 0.01%, if these elements are too high, it will have a certain adverse effect on the toughness properties in the product.

The specific purposes of each step in the above manufacturing method are as follows:

Electric arc furnace smelting: through oxidation and reduction refining, remove P and S, remove oxygen, nitrogen and hydrogen, remove inclusions, control and adjust chemical composition, and obtain relatively pure molten steel.

Ladle furnace refining: Pour the pure molten steel obtained by electric arc furnace smelting into a ladle furnace for refining, further precise control of chemical composition, removal of S and gas.

Vacuum furnace degassing: Pour the purer molten steel adjusted by the ladle furnace into the vacuum furnace, oxygen, decarburization, vacuum degassing, fine tuning of the alloy composition under vacuum, and obtain the final chemical composition with precise control. Pure molten steel (qualified means that it meets the requirements of the technical solution of this application).

Molding: Pour qualified pure molten steel into the ingot type, control the cooling rate of the ingot type to obtain a dense, relatively uniform and less segregated steel ingot, ready for rolling. Bottom casting is used during the molding process.

Initial rolling: The steel ingot obtained by die casting is opened to ensure the uniformity of each part of the ingot and reduce the degree of looseness, so as to prepare for the forging type.

Forging type: The initial rolled billet is subjected to preliminary free forging, and the final forging is performed by die forging.

Dehydrogenation heat treatment: The forged piece is subjected to dehydrogenation treatment to greatly improve the impact toughness of the forging.

Final heat treatment: The forged piece after the dehydrogenation heat treatment is subjected to the final heat treatment of the structure and properties.

It should be noted that the elements to be adjusted are determined by measuring the content of each component in the raw material before the electric arc furnace is smelted, and elemental adjustment and dehydrogenation heat treatment are performed by electric arc furnace smelting, ladle furnace refining, and vacuum furnace degassing. Further, hydrogen is removed to adjust the components of the high-wear-resistant alloy steel for railway skewers of the present invention to an appropriate range.

The process parameters of the electric arc furnace smelting, ladle refining and vacuum degassing in the present invention are process parameters commonly used in the art, and those skilled in the art are regulated according to the common knowledge in the art and the desired group distribution ratio.

The raw material for preparing the high wear-resistant alloy steel for railway frogs of the present invention is generally scrap steel.

If a 75Kg/m frog is manufactured, the final heat treatment may include air cooling to room temperature after austenitizing at 890 ° C to 980 ° C, wherein the austenitizing heat holding time is determined according to the effective thickness of the product, generally 25 mm The thickness was heated for 1 hour to calculate the holding time. The cooling rate is from 0.3 ° C / s to 0.5 ° C / s, and then tempered at 160 ° C ~ 550 ° C, preferably 300 ° C ~ 450 ° C, wherein the tempering temperature is determined according to performance requirements, tempering heating and holding time according to the product Depending on the effective thickness, it is generally possible to heat the thickness of 25 mm for 1.5 hours to calculate the holding time.

For the manufacture of 60Kg/m frog, the final heat treatment may include air cooling to room temperature after austenitizing at 890 ° C to 980 ° C, wherein the austenitizing heating and holding time is determined according to the effective thickness of the product, generally according to 25 mm. The thickness was heated for 1 hour to calculate the holding time. The cooling rate is from 0.5 ° C / s to 0.8 ° C / s, and then tempered at 160 ° C ~ 550 ° C, preferably 300 ° C ~ 450 ° C, wherein the tempering temperature is determined according to performance requirements, tempering heating and holding time according to the product Depending on the effective thickness, the heating time is generally calculated by heating for 1.5 hours at a thickness of 25 mm.

The determination of the effective thickness described in this application can be found in the Handbook of Heat Treatment, 3rd Edition, Volume 1, Process Fundamentals, Mechanical Industry Press, 2001, pp. 40-45.

The present invention will be further described below in conjunction with the embodiments. However, it should be understood by those skilled in the art that the embodiments of the present application are only for the purpose of illustration and not limitation of the scope of the claims.

In the following examples, the component contents are all based on their mass percentage.

In the present application, the standard for determining the tensile properties at room temperature is GB/T228-2002 "Metal Material Tensile Test Method", and the standard for the measurement of impact properties is GB/T229-2007 "Metal Material Charpy Pendulum" Impact test method, the standard used for the conversion method of αKU is GB/T229-1984 "Metal Charpy (U-notch) impact test method", the hardness test is based on GBT 230.1-2009 metal material Rockwell hardness test Part 1: Test methods (A, B, C, D, E, F, G, H, K, N, T scales).

Example 1

Using scrap steel as raw material, firstly determine the components and content of the raw steel, and according to the components required for the target high wear-resistant air-cooled steel and the mass percentage thereof, the raw steel and other raw materials used for the furnishing, such as various ore particles. Mixing, oxidizing and reducing refining by electric arc furnace smelting, removing phosphorus (P) and sulfur (S) and removing oxygen, nitrogen and hydrogen, removing inclusions, controlling and adjusting chemical composition, and obtaining relatively pure molten steel. The pure molten steel obtained by the electric arc furnace smelting is poured into a ladle furnace for refining, and the chemical composition is further precisely controlled to further remove S and gas. Pour the purer molten steel adjusted by the ladle furnace into the vacuum furnace, oxygen, decarburization, vacuum degassing, fine adjustment of the alloy composition under vacuum, and the qualified pure steel water with the precise control of the final chemical composition will be qualified. Pure molten steel is poured into the ingot form to obtain a dense and uniform ingot with a small degree of segregation. The ingot obtained by molding is opened to ensure uniformity of various parts of the ingot and to reduce the degree of looseness. The initially rolled slab was subjected to preliminary free forging, and the final forging was performed by die forging to obtain a forged piece of 75 Kg/m frog. The forged part is subjected to dehydrogenation treatment to greatly improve the impact toughness of the forging. The forged piece after dehydrogenation heat treatment is subjected to final heat treatment of microstructure and properties, and the final heat treatment includes austenitizing at 890 ° C to 980 ° C, then air cooling to room temperature, and the cooling rate is 0.3 ° C / s to 0.5 ° C / s, and then The tempering is carried out at 300 ° C to 450 ° C to obtain the high wear-resistant alloy steel of the present invention, and the components thereof and their mass percentage ratios are: C 0.30, Si 0.52, Mn 1.27, P 0.007, S 0.004, Cr 1.64, Ni 1.29, Mo 0.44, Al 0.07, Nb 0.04, O 18 ppm, N 76 ppm, H 0.36 ppm, the balance being iron and unavoidable impurities.

The mechanical properties were found to be: R _m was 1685 MPa, R _p0.2 was 1367 MPa, hardness was 51.5 HRC, α _KU (room temperature) was 134 J/cm ² , and α _KU (-40 ° C) was 92 J/cm ² .

Example 2

The high wear-resistant alloy steel for railway frogs was prepared by the method described in Example 1, and its components and their mass percentage ratios were: C 0.29, Si 0.45, Mn 1.51, P 0.006, S 0.006, Cr 1.67, Ni 1.47. Mo 0.41, Al 0.05, Nb 0.10, O 18 ppm, N 79 ppm, H 0.43 ppm, the balance being iron and unavoidable impurities. The mechanical properties were found to be: R _m was 1701 MPa, R _p0.2 was 1370 MPa, hardness was 52.0 HRC, α _KU (room temperature) was 112 J/cm ² , and α _KU (-40 ° C) was 79 J/cm ² .

Example 3

The high wear-resistant alloy steel for railway frogs was prepared by the method described in Example 1, and its components and their mass percentage ratios were: C 0.38, Si 0.20, Mn 1.29, P 0.009, S 0.004, Cr 1.75, Ni 1.01. Mo 0.56, Al 0.07, Nb 0.08, O 15 ppm, N 78 ppm, H 0.42 ppm, the balance being iron and unavoidable impurities. The mechanical properties were as follows: R _m was 1723 MPa, R _p0.2 was 1384 MPa, hardness was 52.5 HRC, α _KU (room temperature) was 137 J/cm ² , and α _KU (-40 ° C) was 93 J/cm ² .

Example 4

The high wear-resistant alloy steel for railway frogs was prepared by the method described in Example 1, and its components and their mass percentage ratios were: C 0.33, Si 0.59, Mn 1.01, P 0.009, S 0.001, Cr 1.61, Ni. 1.22, Mo 0.57, Al 0.06, Nb 0.09O 20 ppm, N 75 ppm, H 0.46 ppm, the balance being iron and unavoidable impurities. The mechanical properties were found to be: R _m was 1719 MPa, R _p0.2 was 1377 MPa, hardness was 52.5 HRC, α _KU (room temperature) was 138 J/cm ² , and α _KU (-40 ° C) was 94.5 J/cm ² .

Example 5

The high wear-resistant alloy steel for railway frogs was prepared by the method described in Example 1, and its components and their mass percentage ratios were: C 0.39, Si 0.21, Mn 1.36, P 0.008, S 0.004, Cr 1.72, Ni 1.21 Mo 0.29, Al 0.07, Nb 0.07, O 14 ppm, N 77 ppm, H 0.41 ppm, the balance being iron and unavoidable impurities. The mechanical properties were found to be: R _m was 1625 MPa, R _p0.2 was _{1321 MPa} , hardness was 50.5 HRC, α _KU (room temperature) was 145 J/cm ² , and α _KU (-40 ° C) was 101 J/cm ² .

Example 6

The high wear-resistant alloy steel for railway frogs was prepared by the method described in Example 1, and its components and their mass percentage ratios were: C 0.29, Si 0.30, Mn 1.32, P 0.009, S 0.002, Cr 1.79, Ni 1.24. Mo 0.59, Al 0.02, Nb 0.03, O 20 ppm, N 98 ppm, H 0.35 ppm, the balance being iron and unavoidable impurities. The mechanical properties were as follows: R _m was 1653 MPa, R _p0.2 was 1331 MPa, hardness was 51.0 HRC, α _KU (room temperature) was 129 J/cm ² , and α _KU (-40 ° C) was 88 J/cm ² .

Example 7

The high wear-resistant alloy steel for railway frogs was prepared by the method described in Example 1, and its components and their mass percentage ratios were: C 0.37, Si 0.39, Mn 1.17, P 0.007, S 0.003, Cr 1.54, Ni 1.26. Mo 0.36, Al 0.04, Nb 0.05, O 19 ppm, N 65 ppm, H 0.33 ppm, the balance being iron and unavoidable impurities. The mechanical properties were found to be: R _m was 1631 MPa, R _p0.2 was 1323 MPa, hardness was 50.5 HRC, α _KU (room temperature) was 141 J/cm ² , and α _KU (-40 ° C) was 99 J/cm ² .

Example 8

The high wear-resistant alloy steel for railway frogs was prepared by the method described in Example 1, and its components and their mass percentage ratios were: C 0.38, Si 0.47, Mn 0.92, P 0.007, S 0.001, Cr 1.55, Ni 1.49. Mo 0.37, Al 0.06, Nb 0.06, O 16 ppm, N 82 ppm, H 0.41 ppm, the balance being iron and unavoidable impurities. The mechanical properties were found to be: R _m was 1709 MPa, R _p0.2 was 1374 MPa, hardness was 52.0 HRC, α _KU (room temperature) was 114 J/cm ² , and α _KU (-40 ° C) was 83 J/cm ² .

Example 9

The high wear-resistant alloy steel for railway frogs was prepared by the method described in Example 1, and its components and their mass percentage ratios were: C 0.36, Si 0.41, Mn 1.34, P 0.008, S 0.002, Cr 1.52, Ni 1.08. Mo 0.47, Al 0.06, Nb 0.08, O 17 ppm, N 98 ppm, H 0.45 ppm, the balance being iron and unavoidable impurities. The mechanical properties were found to be: R _m was 1701 MPa, R _p0.2 was 1369 MPa, hardness was 52.0 HRC, α _KU (room temperature) was 119 J/cm ² , and α _KU (-40 ° C) was 91 J/cm ² .

Example 10

The high wear-resistant alloy steel for railway frogs was prepared by the method described in Example 1, and its components and their mass percentage ratios were: C 0.45, Si 0.24, Mn 0.90, P 0.006, S 0.001, Cr 1.58, Ni 1.05. Mo 0.45, Al 0.07, Nb 0.03, O 16 ppm, N 88 ppm, H 0.35 ppm, the balance being iron and unavoidable impurities. The mechanical properties were found to be: R _m was 1629 MPa, R _p0.2 was _{1321 MPa} , hardness was 50.5 HRC, α _KU (room temperature) was 142 J/cm ² , and α _KU (-40 ° C) was 103 J/cm ² .

Example 11

The smelting and forging method of the first embodiment is repeated to prepare a high wear-resistant alloy steel for railway frogs, and is particularly suitable for high wear-resistant alloy steel for a rail 辙 fork of a specification type of 60 Kg/m, and a final heat treatment and a 75 Kg/m frog. The difference is that after austenitizing at 890 ° C to 980 ° C, air cooling to room temperature, the cooling rate is from 0.5 ° C / s to 0.8 ° C / s; and then tempered at 160 ° C ~ 550 ° C. The mechanical properties of the high wear-resistant alloy steel for railway frogs were as follows: R _m was 1701 MPa, R _p0.2 was 1373 MPa, hardness was 52.0 HRC, α _KU (room temperature) was 115 J/cm ² , α _KU (- 40 ° C) was 81 J/cm ² .

Example 12

A set of high wear-resistant alloy steel for high-speed heavy-duty railway frogs was prepared by the method described in Example 1, and its composition and mass percentage were as shown in Table 1 below. After testing, the mechanical properties of the high wear-resistant alloy steel in this set of examples can meet the following requirements: R _m ≥1605MPa, R _p0.2 ≥1300MPa, hardness ≥48HRC, α _KU (room temperature)≥100J/cm ² ,α _KU (-40 ° C) ≥ 70 J / cm ² . The specific results are shown in Table 2.

Table 1 Composition and mass percentage ratio of high wear-resistant alloy steel for railway frogs

Table 2 Mechanical properties of high wear-resistant alloy steel for railway frogs

While some aspects of the present invention have been shown and described, it will be understood by those skilled in the <RTIgt; The content is limited.

Claims (13)

1. A high wear-resistant alloy steel for railway frogs, characterized in that each component and its mass percentage are as follows: C 0.29% to 0.45%, Si 0.20% to 0.59%, Mn 0.90% to 1.51%, P ≤ 0.015% , S ≤ 0.010%, Cr 1.52% to 1.79%, Ni 1.01% to 1.49%, Mo 0.29% to 0.59%, Al 0.02% to 0.07%, Nb 0.025% to 0.10%, 0.05% ≤ Nb + Al ≤ 0.15% , [O] ≤ 20ppm, [N] ≤ 100ppm, [H] ≤ 0.50ppm, the balance is iron and unavoidable impurities.
2. The high wear-resistant alloy steel according to claim 1, wherein the mass percentage of C is 0.29% to 0.34% or 0.35% to 0.39% or 0.40% to 0.45%.
3. The high wear-resistant alloy steel according to claim 1 or 2, wherein the mass percentage of Mn is from 1.01% to 1.51%.
4. The high wear-resistant alloy steel according to claim 1 or 2, wherein the mass percentage of Ni is from 1.01% to 1.31% or from 1.21% to 1.49%.
5. The high wear-resistant alloy steel according to claim 1 or 2, wherein the mass percentage of Mo is from 0.35% to 0.59% or from 0.29% to 0.49%.
6. The high wear-resistant alloy steel according to claim 1, wherein each component and its mass percentage are as follows: C 0.29% to 0.34%, Si 0.20% to 0.59%, Mn 1.01% to 1.51%, P ≤ 0.015. %, S ≤ 0.010%, Cr 1.52% to 1.79%, Ni 1.21% to 1.49%, Mo 0.35% to 0.59%, Al 0.02% to 0.07%, Nb 0.025% to 0.10%, 0.05% ≤ Nb + Al ≤ 0.15%, [O] ≤ 20 ppm, [N] ≤ 100 ppm, [H] ≤ 0.50 ppm, and the balance is iron and unavoidable impurities.
7. The high wear-resistant alloy steel according to claim 1, wherein each component and its mass percentage are as follows: C 0.35% to 0.39%, Si 0.20% to 0.59%, Mn 0.90% to 1.51%, P ≤ 0.015. %, S ≤ 0.010%, Cr 1.52% to 1.79%, Ni 1.01% to 1.49%, Mo 0.29% to 0.59%, Al 0.02% to 0.07%, Nb 0.025% to 0.10%, 0.05% ≤ Nb + Al ≤ 0.15%, [O] ≤ 20 ppm, [N] ≤ 100 ppm, [H] ≤ 0.50 ppm, and the balance is iron and unavoidable impurities.
8. The high wear-resistant alloy steel according to claim 1, wherein each component and its mass percentage are as follows: C 0.40% to 0.45%, Si 0.20% to 0.59%, Mn 0.90% to 1.51%, P ≤ 0.015. %, S ≤ 0.010%, Cr 1.52% to 1.79%, Ni 1.01% to 1.31%, Mo 0.29% to 0.49%, Al 0.02% to 0.07%, Nb 0.025% to 0.10%, 0.05% ≤ Nb + Al ≤ 0.15%, [O] ≤ 20ppm, [N] ≤ 100ppm, [H] ≤ 0.50ppm, the balance is Iron and inevitable impurities.
9. The high wear-resistant alloy steel according to claim 1, wherein the mechanical properties of the high wear-resistant alloy steel are as follows: R _m ≥ 1605 MPa, R _p0.2 ≥ ₁₃₀₀ MPa, hardness ≥ 48 HRC, α _KU (room temperature) ) ≥ 100 J/cm ² , α _KU (-40 ° C) ≥ 70 J/cm ² .
10. The method for producing high wear-resistant alloy steel for railway frog according to any one of claims 1 to 9, characterized in that the manufacturing method comprises the following steps in sequence: electric arc furnace smelting → ladle furnace refining → vacuum Furnace degassing→die casting→initial rolling blanking→forging type→dehydrogenation heat treatment→final heat treatment; wherein the forging type adopts free forging and die forging, and the final heat treatment includes 0.1°C/s to 0.8°C after austenitizing. /s is controlled to cool, cooled to room temperature and then tempered.
11. The method for manufacturing a high wear-resistant alloy steel according to claim 10, wherein the final heat treatment comprises austenitizing at 890 ° C to 980 ° C and then air cooling to room temperature, and the cooling rate is from 0.3 ° C / s to 0.5 ° C. /s; then temper at 1200 ° C ~ 550 ° C.
12. The method for manufacturing a high wear-resistant alloy steel according to claim 10, wherein the final heat treatment comprises austenitizing at 890 ° C to 980 ° C and then air cooling to room temperature, and the cooling rate is from 0.5 ° C / s to 0.8 ° C. /s; then temper at 1200 ° C ~ 550 ° C.
13. The method for producing a highly wear-resistant alloy steel according to claim 11 or 12, wherein the tempering temperature is in the range of 300 ° C to 450 ° C.