RU2716326C1 - Method of obtaining high-alloy heat resistant alloys on nickel base with titanium and aluminium content in narrow range - Google Patents

Abstract

FIELD: metallurgy.

SUBSTANCE: invention relates to special metallurgy, specifically to methods of producing high-alloy heat-resistant nickel-based alloys with titanium and aluminium content within narrow limits. Proposed method comprises melting of heat-resistant alloy containing, in wt. %: primary charge - 30–40, standard process wastes - 20–30, secondary condition waste in form of passport charge blank is balance. Passport mixture charge is obtained using waste recycling. Casting of the electrode and subsequent refining is performed at melting rate 2.5 to 4.5 kg/min to produce ingots with diameter from 150 to 630 mm.

EFFECT: technical result is obtaining high-quality ingots of heat-resistant alloys with content of titanium and aluminium in narrow ranges with stable mechanical properties.

4 cl, 3 tbl, 1 dwg, 1 ex

Description

1. The technical field

The invention relates to the field of special metallurgy, and specifically to methods for the production of highly alloyed heat-resistant nickel-based alloys with titanium and aluminum contents within a narrow range used for the manufacture of aircraft parts (gas turbine blades, heat-treated and turned stampings of disks, baffles, labyrinths), and parts of power engineering and turbine engineering, solid-rolled rings for various purposes. The method includes smelting a heat-resistant alloy using a passport charge plate with a high content of titanium and aluminum obtained using waste recovery, casting the electrode into a mold suitable for refining, and subsequent refining with a melting rate of 2.5 to 4.5 kg / min to obtain ingots with a diameter of 150 to 630 mm The method provides resource-saving due to waste recovery, including saving expensive and scarce charge materials and makes it possible to obtain high-quality ingots of heat-resistant alloys with titanium and aluminum contents within narrow limits, which guarantees the stability of the mechanical properties of the finished products.

2. The prior art

The well-known "Method for producing casting heat-resistant nickel-based alloys" (Patent RU 2470081 (С22С 1/02, С22В 9/02), 2011), including the preparation of charge materials containing waste heat-resistant nickel alloys, and their subsequent remelting in vacuum. The disadvantage of the technical solution is the inability to adjust the composition in preparation for the main smelting.

The well-known "Method for producing heat-resistant nickel alloys by processing metal waste" (Patent RU 2398905 (C22C 19/03, C22 B 7/00), 2009), including the loading of metal waste, their melting and refining in vacuum. The disadvantage of this method is the impossibility of providing in the metal low contents of harmful impurities and non-metallic inclusions, as well as a limitation on the amount and type of waste introduced.

The well-known "Method for producing superalloys based on nickel alloyed with rare-earth metals" (Patent RU 2572117 (С22С 19/03, С22С 1/02), 2014), comprising loading a charge into the melting crucible in the form of metal waste or a mixture of metal waste and alloying metals, introducing a refining additive into the mixture, melting the mixture, and pouring the obtained melt through a filter. The disadvantage of this method is that the technical solution does not provide for waste treatment.

Also known, adopted by the applicant for the closest analogue, “A method for producing a high-alloy heat-resistant alloy KhN62BMKTY on a nickel basis” (Patent RU 2672651 (С22С 1/02, С22 В 9/20), 2017). The method includes cleaning substandard waste, reducing waste melting in a direct current arc furnace with melt blowing with oxygen, subsequent refining vacuum arc remelting, and using the resulting secondary waste in the smelting of grade metal.

The disadvantages of the method include significant labor costs associated with the need to obtain secondary activated waste, pure non-metallic and slag inclusions, to ensure a guaranteed chemical composition.

3. The invention

3.1. Statement of the technical problem

Resource-saving (saving expensive and scarce charge materials) in the smelting of high-alloy nickel-based alloys using substandard waste generated at all stages of the preparation and production of metal products (gates, scrap, profitable parts of open ingots, shavings, technological trimmings) by recuperation, as well as obtaining in heat-resistant alloys the content of titanium and aluminum within narrow limits, which guarantees the stability of the mechanical properties of the finished products.

The result of solving a technical problem

The resource-saving task was solved by involving in the production of high-alloy heat-resistant alloys, including alloys ХН77ТЮР (У), ХН73МБТЮ, ХН62 ВМЮТ, recovered (secondary conditioned) wastes obtained by preparation and smelting of a passport charge blank with a high content of titanium and aluminum from substandard waste generated all stages of preparation and production of metal products. Moreover, the resulting secondary conditioned waste provides a high content of titanium and aluminum.

3.2. Features

In contrast to the well-known technical solution, including the cleaning of substandard waste, the recovery smelting of waste in a direct current arc furnace with melt blowing with oxygen, the subsequent refining vacuum arc remelting, and the use of the resulting secondary waste in the smelting of grade metal; in the claimed technical solution at the stage of preparing charge materials from substandard waste, for their recovery and obtaining secondary conditioned waste, to produce highly alloyed heat-resistant alloys based on nickel with titanium and aluminum contents within narrow limits, sequentially smelting substandard waste with by adjusting the chemical composition of the melt for titanium and aluminum, secondary conditioned waste obtained after recovery (passport charge blank with a high content of titanium and aluminum) together with conditioned technological waste is introduced into the composition of the mixture of smelting of grade metal in the ratio of components:

- primary charge - 30 ÷ 40%;

- conditioned technological waste - 20 ÷ 30%;

- recovered (secondary conditioned) waste (passport charge blank with a high content of titanium and aluminum) - the rest

and they carry out the regular mode of smelting of grade metal in a DC arc furnace, casting the electrode into a mold suitable for refining remelting, and subsequent refining remelting to produce ingots with diameters from 150 to 630 mm.

The charge filling for the recovery of substandard waste and the production of secondary conditioned waste is formed using up to 100% calcined shavings (process waste, return of own production) identical to a heat-resistant alloy. Pre-dried lime and fresh flux ANF-1, ANF-6 are used as slag-forming substances.

In order to prevent overheating of the melt and increased fumes of elements (titanium and aluminum), melting is carried out in a certain electric and temperature mode, and the additives of titanium and aluminum are strictly regulated.

At the end of the melting period at a temperature of n.b. 1510 ° C add the calculated amount of titanium and aluminum. After giving the first portion of titanium and aluminum, the temperature of the metal increases; for its cooling, metal chromium is added to the melt in an amount of not more than 100 kg.

After complete assimilation of titanium and aluminum, the metal is held in the furnace for 25 ÷ 30 minutes at the minimum electrical parameters and at a temperature of not more than 1540 ° C, the passport charge ingots with a high content of titanium and aluminum are cast into molds, if possible by small weight.

Before using the melted passport charge ingots with a high content of titanium and aluminum, continuous abrasive cleaning of the side surface of the ingots to a depth of 8-10% of the diameter of the ingot is performed.

Prepared ingots of passport charge ingots with a high content of titanium and aluminum are used for the smelting of grade metal in an amount of up to 50% by weight of the filling as secondary conditioned (recovered) waste.

Smelting of grade metal is carried out in a direct current arc furnace by fusion.

After pouring the grade metal and holding it for a certain period of time sufficient for hardening so that it can be safely removed from the mold, the electrodes are prepared for further refining by recessing by cutting turning to a depth of 15 ÷ 20% of the ingot diameter.

Refining vacuum arc remelting of prepared electrodes is carried out using helium to reduce the depth of a liquid bath in order to refine it more completely. VD remelting is carried out in crystallizers with a diameter of 150 to 630 mm with a remelting rate of 2.5 ÷ 4.5 kg / min and a discharge in the furnace chamber of 1-10 ^-2 ÷ 10 ^-3 mm Hg.

3.3. List of drawings

In FIG. 1 is a structural flowchart of a method for producing highly alloyed heat-resistant alloys, including KhN77TYuR (U), KhN73MBTYu, KhN62VMYuT alloys and other nickel-based alloys with titanium and aluminum contents within narrow limits, where 1. - Formation of a furnace filling for smelting grade metal; 1a. - “Fresh” (standard) charge components; 1b. -Correcting charge components (alloying additives); 2. - Open smelting of grade metal in a direct current arc furnace (DPPT); 3. - Casting electrodes of open smelting; 4. - Processing of electrodes of open smelting; 5. - Refining vacuum arc remelting of electrodes (VDP); 6. - Production of grade metal; 7. - Substandard waste (7-1. - Underfilling, scrap, 7-2. - Profitable parts, 7-3. - Underflooding, 7-4. - Chips); 8. - Conditioned technological waste (8-1. - Technological trimmings, 8-2. - Residues from cutting); 9. - Formation of the filling of the furnace from substandard waste; 10. - Mechanical cleaning and processing of substandard waste; 11. - Smelting of a passport charge blank with a high content of titanium and aluminum in an open direct current arc furnace (DPPT); 12. - Casting ingots of a passport charge blank with a high content of titanium and aluminum; 13. - Processing of ingots of passport charge ingots with a high content of titanium and aluminum; 14. - Recovered (secondary conditioned) waste;

DPPT - DC Arc Furnace in FIG. 1 block 2 and 11;

VDP — Vacuum Arc Remelting in FIG. 1 block 5.

4. Description of the invention

In the claimed technical solution, in order to obtain heat-resistant nickel-based alloys with titanium and aluminum contents within narrow limits, at the stage of preparation of charge materials, substandard waste is recovered, and the following operations are performed sequentially (Fig. 1):

- preliminary melting in a direct current arc furnace of substandard waste (sprues, scrap, profitable parts of open ingots, shavings, technological trimmings) (Fig. 1, block 7) identical to the heat-resistant alloy by fusion, with adjustment of the chemical composition of the melt in titanium and aluminum, and obtaining a passport charge blank with a high content of titanium and aluminum - secondary conditioned waste;

- smelting of grade metal in a direct current arc furnace (DPPT) using the obtained passport charge plate with a high content of titanium and aluminum, casting the electrodes into a mold suitable for refining remelting, and subsequent refining remelting to produce ingots with diameters from 150 to 630 mm (Fig. . 1, block 1-5).

The filling of a direct current arc furnace for smelting a passport charge blank with a high content of titanium and aluminum is formed using shavings (up to 100% of the filling weight) and lumpy substandard waste identical to a heat-resistant alloy. As slag-forming agents, pre-dried lime and fresh flux ANF-1, ANF-6 are used (Fig. 1, block 9).

Chips and other metalworking waste are preliminarily calcined in an annealing furnace in a cast-iron brazier with a bulk layer of not more than 600–700 mm at a temperature of 500–600 ° C for 2–3 hours. The cooling of metalworking waste is carried out with the furnace for 7 ÷ 8 hours to a temperature of 60 ÷ 80 ° C (Fig. 1, block 10).

Smelting of a passport charge blank with a high content of titanium and aluminum in a DC arc furnace is carried out by fusion, with the correction of the chemical composition of the melt in titanium and aluminum (Fig. 1, block 11).

In order to prevent overheating of the melt and increased fumes of elements (titanium and aluminum), melting is carried out in a certain electric and temperature mode, and the additives of titanium and aluminum are strictly regulated.

Temperature and electrical melting is the following methods:

a. The charge is melted at maximum power.

b. The temperature of the molten metal in the melt is 1500 ÷ 1520 ° C.

in. At the end of the melting period at a temperature of n.b. 1510 ° C add the calculated amount of titanium and aluminum. After giving the first portion of titanium and aluminum, the temperature of the metal increases; for its cooling, metal chromium is added to the melt in an amount of not more than 100 kg. In order to reduce the temperature of the metal to 1500 ÷ 1520 ° C and reduce the burning of titanium and aluminum, further additives are produced with the furnace turned off. During the addition of metal to aluminum and titanium, the slag is not deoxidized.

d. After the complete assimilation of titanium and aluminum, the metal is held in the furnace for 25–30 minutes at the minimum electrical parameters and at a temperature of not more than 1540 ° C, they are cast into molds, if possible by weight.

Before using the melted passport charge ingots with a high content of titanium and aluminum, continuous abrasive cleaning of the side surface of the ingots to a depth of 8 ÷ 10% of the diameter of the ingot is performed (Fig. 1, block 13).

Prepared ingots of passport charge ingots with a high content of titanium and aluminum are used for smelting grade metal in an amount up to 50% of the weight of the filling as secondary conditioned waste (Fig. 1, block 14).

Smelting of grade metal is carried out in a direct current arc furnace by fusion (Fig. 1, block 2). The ratio of components in the metal charge:

- primary charge - 30 ÷ 40%;

- conditioned technological waste - 20 ÷ 30%;

- recovered (secondary conditioned) waste (passport charge blank with a high content of titanium and aluminum) - the rest.

After pouring the grade metal and holding it for a certain period of time sufficient for hardening so that it can be safely removed from the mold, the electrodes are prepared for further refining in the mold with a diameter of 150 to 630 mm by cutting by turning to a depth of 15 ÷ 20% of the ingot diameter (Fig 1., block 3).

The refining remelting of consumable electrodes in a vacuum arc furnace is based on vacuum melting a metal billet with a high-power electric arc and simultaneous crystallization of the metal in a water-cooled mold. In a vacuum arc remelting, impurities are removed at the end of the electrode and from the surface of the liquid bath. Two reaction zones with a developed interaction surface with a relatively small volume of molten metal, the action of an electric arc and vacuum on a liquid metal provide the development of the necessary refining processes. In order to more fully refine the melted metal and reduce the depth of the liquid metal bath, the vacuum arc remelting of the prepared electrodes is carried out in crystallizers with a diameter of 150 to 630 mm using helium with a deposition rate of ingots of 2.5 ÷ 4.5 kg / min. the furnace chamber 110 ^-2 ÷ 10 ^-3 mm RT. Art.

Using the proposed method allows the recovery of substandard waste generated at all stages of the preparation and production of metal products (gates, scrap, profitable parts of open ingots, shavings, technological trimmings).

The application of the proposed method allows smelting a passport charge plate with a high content of titanium and aluminum, which ensures that titanium and aluminum are obtained in heat-resistant alloys within narrow limits, which guarantees the stability of the mechanical properties of the finished products, and also saves expensive and scarce charge materials during smelting of grade metal ( nickel, chromium, molybdenum, niobium).

5. An example of a specific implementation (implementation of the method)

The method can be implemented on the integrated installation of standard equipment:

a. chip annealing is carried out in a single chamber gas furnace with a retractable

hearth;

b. smelting of a passport charge blank with a high content of titanium and aluminum, using substandard waste, is carried out in a 5-ton DC arc furnace;

in. continuous abrasive cleaning of ingots of a passport charge blank with a high content of titanium and aluminum is carried out on an abrasive-cleaning machine and the removal of technological scrap on both sides on a cutting machine;

d. smelting of grade metal using a passport charge ingot with a high content of titanium and aluminum is carried out in a direct current arc furnace with a capacity of 5.0 tons;

D. processing of the obtained electrodes for subsequent refining remelting is carried out on a RT-503 ingot-peeling machine;

E. Vacuum arc remelting with the production of ingots for the subsequent manufacture of the final metal products with a diameter of 150 to 630 mm is carried out on DSV and CEP furnaces.

The composition of the filling for smelting a passport charge blank with a high content of titanium and aluminum in an open direct current arc furnace: 10% of its own lumpy waste, 10% of chrome metal and 80% of chips (return of own production), previously cleaned as follows:

- calcination in an annealing single-chamber gas furnace with a roll-out hearth in a cast-iron brazier with a bulk layer of not more than 600 ÷ 700 mm at a temperature of 500 ÷ 600 ° C for 2 ÷ 3 hours;

- cooling with the furnace for 7 ÷ 8 hours to a temperature of 60 ÷ 80 ° C.

Pre-dried lime and fresh flux ANF-1, ANF-6 were used as slag-forming substances.

Then, smelting in a 5-ton open direct-current arc furnace of substandard waste was performed by fusion in a certain electric and temperature mode with strictly regulated titanium and aluminum additives.

After complete assimilation of titanium and aluminum, the metal was held in the furnace for 25–30 minutes at the minimum electrical parameters and, at a temperature of no more than 1540 ° C, was cast into molds. Table 1 shows the chemical composition of the melted, using substandard waste, passport charge blanks with a high content of titanium and aluminum alloy ХН73МБТЮ (secondary conditioned waste).

Next, the side surface of the melted passport charge plate with a high content of titanium and aluminum was subjected to continuous abrasive cleaning on a peeling-grinding machine to a depth of 8 ÷ 10% of the ingot diameter before being used for smelting grade metal and the technological trim on both sides was removed on a cutting machine.

The prepared passport charge blank with a high content of titanium and aluminum was used for the smelting of grade metal alloy ХН73МБТЮ in an open direct current arc furnace as secondary conditioned waste in an amount of up to 50% of the weight of the heat. This made it possible to reduce the silicon content in the specified charge materials by 1.3 times and to ensure the titanium and aluminum content in the grade metal within narrow limits (titanium 2.35 ÷ 2.75%, aluminum 1.45 ÷ 1.80%), which guaranteed stability of mechanical properties of finished products.

Table 2 shows the chemical composition of the grade metal of the KhN73MBTY alloy melted using a passport charge blank with a high content of titanium and aluminum (secondary conditioned waste).

Refining vacuum arc remelting of prepared consumable electrodes of grade metal was carried out in crystallizers with a diameter of 320, 400 and 500 mm using helium with a deposition rate of ingots from 2.8 to 3.8 kg / min, when discharged in the furnace chamber 1⋅10 ^-2 ÷ 10 ^-3 mmHg

Table 3 shows the results of control tests of metal products from the KhN73MBTY alloy, smelted using secondary conditioned waste (passport charge blanks with a high content of titanium and aluminum).

From table 3 it can be seen that the properties of the metal smelted using a passport charge blank with a high content of titanium and aluminum meet the requirements and have a margin for all characteristics.

The claimed technical solution was tested in a production environment at JSC Metallurgical Plant Elektrostal with a positive result.

The use of the invention for the production of high-alloy heat-resistant alloys based on nickel with a titanium and aluminum content within a narrow range (for example, KhN73MBTYu alloy) allows to draw substandard waste into production, returning scarce and expensive materials to production and smelting a passport charge plate with a high content of titanium and aluminum , providing obtaining in heat-resistant alloys the content of titanium and aluminum in a narrow range, which guarantees the stability of the mechanical properties of the finished product.

Claims (8)

1. A method for producing highly alloyed heat-resistant nickel-based alloys with a narrow titanium and aluminum content, including cleaning of substandard waste, reducing waste melting in a direct current arc furnace with melt blowing with oxygen, subsequent refining vacuum arc remelting and using the resulting secondary waste for smelting vintage metal, characterized in that at the stage of preparation of charge materials from substandard waste for their recovery and obtaining secondary conditions These wastes are subsequently smelted in a DC arc furnace of substandard waste with adjustment of the chemical composition of the melt in titanium and aluminum; secondary conditioned waste obtained after recovery in the form of a passport charge pig (PSB) with a high content of titanium and aluminum together with conditioned technological waste is introduced into the composition charge for smelting of branded metal in the ratio of components, wt.%: - primary charge - 30 ÷ 40; - conditioned technological waste - 20 ÷ 30; - secondary conditioned waste in the form of PShB - the rest, and they carry out the smelting of the branded metal in a direct current arc furnace, casting the electrode into a mold suitable for the refining remelting, and the subsequent refining remelting to produce ingots with a diameter of 150 to 630 mm. 2. The method according to p. 1, characterized in that the smelting in the constant current arc furnace PSB is carried out from substandard waste by the fusion method, with adjustment of the chemical composition of the melt in titanium and aluminum. 3. The method according to p. 1, characterized in that in order to prevent overheating of the PSB metal melt and increased burning of titanium and aluminum, melting is carried out in a temperature regime of 1500 ÷ 1520 ° C, the calculated amount of titanium and aluminum is added at the end of the melting period, and after full assimilation of titanium and aluminum extracts the metal in the furnace for 25–30 minutes at the minimum electrical parameters, after which they are cast into molds at a temperature of 1540 ° C. 4. The method according to p. 1, characterized in that the refining remelting with obtaining ingots with a diameter of 150 to 630 mm is carried out with a melting rate of 2.5-4.5 kg / min when discharged in the furnace chamber 1 камере10 ^-2 ÷ 10 ^-3 mmHg

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