RU2649218C1 - Method for forming anti-corrosive coating on articles from low-carbon steel - Google Patents

Abstract

FIELD: technological processes.

SUBSTANCE: invention relates to electron beam surfacing and can be used to improve the corrosion resistance of steel, used for the manufacture of products in oil and gas chemistry and cryogenic equipment, operating under the influence of corrosive media, in particular for the production of condensers, heat exchangers, digesters, refining reactors, distillation of crude oil and gasoline, transportation and storage of liquid gases. Method for forming an anticorrosive coating of stainless steel on a low-carbon steel product includes applying onto the surface a mixture of flux powders and a powder, containing alloying elements in a ratio, providing a predetermined composition of the stainless steel coating, or a plate previously made of an alloy, containing alloying elements in a ratio sufficient to ensure a coating corresponding to the desired stainless steel grade, and performing electron-beam surfacing of the applied mixture or plate with a relativistic electron beam, wherein the total mass thickness of the powder placed on the surface is determined by the formula: σ=K⋅(E-b), where σ – mass thickness of the deposited powder [g⋅cm^-2], K=0.4…0.5 [g⋅cm^-2⋅MeV^-1], E is the electron energy in the beam [MeV], b=0.3 [MeV].

EFFECT: invention is designed to create on the surface of products made of low-carbon steels a resistant anticorrosion coating, corresponding to the chemical composition of stainless steels, with increased corrosion resistance to oxidizing acids.

7 cl, 5 ex, 10 tbl, 16 dwg

Description

The present invention relates to electron beam surfacing and can be used to increase the corrosion resistance of steel. Coated molding materials are intended for the manufacture of products in petrochemical chemistry and cryogenic engineering operating under the influence of aggressive environments, in particular for the production of condensers, heat exchangers, digesters, reactors for refining, distillation of crude oil and gasoline, transportation and storage of liquid gases.

Currently, stainless steels are widely used as corrosion-resistant structural materials. The main disadvantage of corrosion-resistant iron-carbon alloys is their high cost compared to carbon steels, due to the need to alloy them with such expensive elements as nickel and chromium in large quantities. One of the ways to increase the economic feasibility of using such materials is to form surface layers on the surface of carbon steels corresponding in chemical composition to stainless steels.

A known method of increasing the corrosion resistance of materials (1. Corrosion resistance of friction surfaced AISI 304 stainless steel coatings / H. Khalid Rafi, G. Phanikumar, K. Prasad Rao // Journal of Materials Engineering and Performance. - Vol. 22 (2), 2013, 360-370 pp.), According to which the application of a corrosion-resistant coating is carried out by the method of friction. AISI 304 stainless steel bar rotates at a speed of 800 rpm above the main material, which was used as low-carbon steel AISI 1012. The axial load on the bar is 10 kN. The main material moves along the bar at a speed of 4.4 mm / s. The heat released during friction promotes the formation of plastic layers on the surface of the base material.

However, when using the known method, the width of the layer deposited in one pass is limited by the diameter of the bar, which complicates the processing of large-sized products and reduces the productivity of the process.

The known method (2. Corrosion behavior of wire-arc-sprayed stainless steel coating on mild steel / Z. Zeng, N. Sakoda, and T. Tajiri // Journal of Thermal Spray Technology. - Vol. 15 (3), 2006, 431-437 pp.), According to which the technology of electric arc spraying is used to create a corrosion-resistant material. Molten wire particles made of austenitic steel are applied to a surface of mild steel using a stream of air or nitrogen at a pressure of 380 kPa. The arc spraying mode is as follows: arc voltage 30 V, current 300 A, spraying distance 150 mm, gas flow rate 2.1 расход10 ^-2 m ³ / s. The coating thickness was 500 μm.

The disadvantage of this method is the significant porosity of the resulting coating and poor adhesion of the coating material to the base metal. The noted technology leads to the formation of corrosion-resistant layers of small thickness, which will not provide the required product protection during operation. In addition, during the deposition process, it is possible to burn out alloying elements along with increased oxidation of the sprayed metal and the formed layer.

The closest technical solution adopted for the prototype is the method of forming protective coatings on steel using electron beam surfacing (3. The structure and properties of corrosion-resistant coatings obtained by electron beam surfacing in an air atmosphere / I.M. Poletika, Yu .F. Ivanov, M.G. Golkovsky, T.A. Krylova, M.V. Perovskaya // Materials science and heat treatment of metals. - 2009. - No. 12 (654). S. 33-39). In the known method for creating a corrosion-resistant surface layer, a layer of a modifying component is applied to the steel surface to be treated, for which chromium carbide Cr ₃ C _{2 was used} . To protect against weathering, 10% borax was added to the surfacing mixture. This method made it possible to form a coating up to 2.5 mm thick.

The disadvantage of this method is that in order to strengthen the coating, carbon is included in the composition of the modifying component, which contributes to the precipitation of chromium carbides along the grain boundaries. The concentration of chromium at the grain boundaries falls below the limit that provides corrosion resistance, that is, less than 12%. This contributes to the active development of intergranular corrosion in chromium-depleted zones. As a result of the formation of carbides, not only the stability of the oxide film is reduced, but also the plastic properties of the steel. In addition, the impurities that make up the steel can segregate at grain boundaries and, thus, lead to the formation of a weak passivating film, the rapid dissolution of which leads to corrosion along the grain boundaries.

The objective of the invention is the creation of a highly efficient method for producing layered structural metal materials, characterized by increased corrosion resistance to oxidative acids. The proposed technical solution is based on a method consisting in forming a protective layer several millimeters thick on low-carbon steel products, identical in composition to one of the grades of corrosion-resistant steel.

The problem is solved due to the fact that in the claimed technical solution, they place on the surface of the workpiece a mixture of flux powders and powder containing alloying elements in a ratio that provides a given stainless steel coating composition and conducts electron beam welding of the deposited mixture by a relativistic electron beam, and the overall the mass thickness of the powder layer placed on the surface of the powder, including flux and components containing alloying elements, is determined by the formula:

σ = K⋅ (Е-b),

where σ is the mass thickness of the deposited powder [g⋅cm ^-2 ],

K = 0.4 ... 0.5 [g⋅cm ^-2 ⋅ MeV ^-1 ], E is the electron energy in the beam [MeV], b = 0.3 [MeV]

Preferably, CaF ₂ , LiF, MgF ₂ salts are introduced into the composition of the deposited mixture of powders as fluxing components providing protection against atmospheric action.

Preferably, the anticorrosion coating deposited on the product is, if necessary, subjected to heat treatment to fix the austenitic phase.

Preferably, surfacing is carried out at an electron energy in the beam of at least 1 MeV.

Preferably, the electron beam is removed into an inert gas medium at atmospheric pressure.

Preferably, surfacing on the surface to be processed is repeated many times depending on the required concentration of alloying components in the deposited layer and its thickness.

The problem is also solved due to the fact that in the claimed technical solution on a low-carbon steel product, electron beam surfacing is performed by a relativistic electron beam previously placed on the treated surface of the plate containing alloying elements in a ratio sufficient to ensure the formation of a corrosion-resistant steel base after surfacing coating corresponding to the required grade of stainless steel, and weather protection is provided by t self-fluxing properties of the elements contained in the plate.

Salient features of the proposed method are:

- metals, such as chromium, nickel, molybdenum, copper, iron, titanium, manganese, aluminum, or some of them in the form of a mixture of powders or a plate of their alloy are used as an alloying component;

- the above metals used to prepare the modifying material are used in a ratio sufficient to ensure, after surfacing, the formation on the products of low carbon steel of an anti-corrosion coating corresponding to the required grade of stainless steel.

The problem is solved thanks to a combination of essential distinguishing features.

The technical result achieved by the claimed method is to create on the surface of products from low carbon steels a stable anti-corrosion coating, corresponding in chemical composition to stainless steels, with increased indicators of corrosion resistance to oxidative acids.

The inventive method of forming a protective layer provides a high efficiency process and allows you to form coatings on products of unlimited sizes, if the coating is carried out in atmospheric conditions.

If necessary, to obtain a coating of high purity or with an increased doping concentration due to the absence of flux, the process can be carried out in an inert gas atmosphere. In this case, the beam is removed into the inert gas medium at atmospheric pressure.

The introduction of a large amount of chromium and nickel into the alloy preserves the austenitic state in the steel structure over the entire temperature range, which provides high mechanical properties, a low tendency to grain growth, increases corrosion resistance and the cold brittleness threshold. Chromium, which is part of the alloy, promotes the formation on the surface of a dense protective film of the type (Cr, Fe) ₂ O ₃ , which provides an increase in the electrochemical potential and the transition of the steel into a passive state with respect to the aggressive medium. The introduction of nickel into the alloy contributes not only to an increase in the mechanical properties of steels due to the formation of an austenitic structure, but also facilitates the formation of a barrier layer that prevents the formation of pitting and crevice corrosion. Nickel and chromium, which are part of the steels, form on the surface an oxide layer containing spinel, for example, NiO⋅Cr ₂ O ₃ and FeO⋅Cr ₂ O ₃ . It is more resistant to corrosion than Cr ₂ O ₃ oxide. Manganese can be used as a substitute for nickel in austenitic steels. The introduction of titanium into the alloy reduces the likelihood of the formation of Cr ₂₃ C ₆ carbides. Since titanium has a higher affinity for carbon in comparison with chromium, titanium carbides are released; accordingly, the concentration of chromium in the solid solution does not change. The introduction of titanium enhances the mechanical properties of the alloys due to grain refinement, and also eliminates the possibility of intergranular corrosion with a Ti / C ratio of less than 8.

To increase the stability of alloys against corrosion damage, molybdenum alloying is used. In the process of passivation, molybdenum dissolves with the release of molybdate ions, which, interacting with chromium oxides, form mixed oxides, covering the material with a stable protective layer. The introduction of 2 ... 4% molybdenum into the alloy helps to increase the mechanical properties of the alloys at high temperature. In addition, alloys with the addition of molybdenum are used when there is a risk of pitting corrosion and hydrogen sulfide embrittlement. The additive in molybdenum and copper in austenitic steels while increasing the nickel content contributes to an increase in the corrosion resistance of alloys in acids. High acid resistance along with high mechanical properties are characteristic of Cr-Ni-Mo-Cu-Ti-Al steel. The release of dispersed phases Ni ₃ (Ti, Al) contribute to the intermetallic hardening.

When coating is formed due to the heat accumulated by the molten powder, the base layer under the powder layer melts and the alloying component is diluted with the base metal. In order to achieve the maximum degree of alloying of the deposited layer, the mass thickness of the powder layer o is selected by the formula:

σ = K * (E-b), (1)

where σ is the mass thickness of the deposited powder [g * cm-2], K = 0.4 ... 0.5 [g * cm-2 * MeV-1], E is the electron energy in the beam [MeV], b = 0, 3 [MeV]. In formulating this condition, we proceeded from the Katz and Penfield formula for the mass thickness of the total absorption of the beam depending on the initial electron energy E (7. L. Katz, AS Penfold. Range-energy relations for electrons and the determination of beta-end-point energies by absorption. Revs. Modern Phys., v. 24 (1952), No. 1, p. 28-44), however, the mass thickness determined by the Katz and Penfield formula was reduced by 20-30%, because according to the shape of the distribution of energy losses with the penetration of electrons into the material, the first 80% of the path accounts for almost all of the electron energy, the remaining 20% howl ”of the distribution - only a small fraction of the initial energy. With an increase in the thickness of the powder layer over σ = 0.5⋅ (E-b), i.e. at K> 0.5, the part adjacent to the base will not be directly heated by electrons, while indirect heating due to thermal conductivity will require a multiple increase in processing time, due to poor thermal conductivity of the powder, which will lead to burnout of the flux and oxidation of the coating. With a decrease in the mass thickness of the powder layer below σ = 0.4⋅ (Е-b), i.e. at K <0.4, the degree of doping of the coating decreases due to increased penetration of the base material into the melt.

The use of electromagnetic sweep during surfacing allows you to deflect the electron beam from the vertical by an angle of up to 30 °, scanning the surface of the workpiece with a beam. The scanning frequency is selected large enough to ensure uniform exposure of the beam to all points on the surface of the material during its movement.

The energy introduced into the unit area of the processed material is determined by the current strength of the electron beam, the accelerating voltage of the electron beam, the scanning width of the electron beam and the speed of movement of the processed material. Given the accelerating voltage and scanning beam width of the electron beam, the current strength and speed of the product must be selected so that the melting mixture and a thin surface layer of the base material completely melt and the powder components do not burn out.

With the bulk thickness of the bulk, defined by formula (1), the beam is almost completely absorbed in the powder layer, heats and melts it. Due to the heat accumulated by the molten powder, the base layer under the powder layer melts and the alloying component is diluted with the base metal. By mixing the molten powder layer with the base metal, a high bond strength of the base composition — the deposited layer — is ensured. Despite the dilution of the base metal, the concentration of the alloying component in the deposited layer remains sufficient to provide a given chemical composition of the deposited layer. At a lower bulk density, a significant part of the beam energy will be released in the base material, intense melting of the base material will occur, which will lead to an increase in the degree of dilution of the alloying elements with the base material and, consequently, a decrease in the concentration of alloying elements. An increase in the bulk thickness of the filler over the value determined by formula (1) will lead to the fact that the electron beam does not penetrate into the lower layer of the powder, its heating, taking into account the low thermal conductivity of the powder, will occur very slowly only due to overlying layers. As a result, the base material will remain in a solid state, and the upper layers of the powder will be overheated. In this case, the necessary adhesion strength of the coating to the base will not be provided.

The technology of electron beam welding is the most cost-effective to create surface layers identical in composition to special acid-resistant steel grades, such as 10X17H13M2T, 06X23N28M3D3T, due to their high cost.

Examples of the method.

Example 1. The formation of anti-corrosion coatings of identical steel grade 12X18H10T

An ELV-6 industrial electron accelerator, commercially available at the Institute of Nuclear Physics of the Siberian Branch of the Russian Academy of Sciences, is used as a source of a relativistic electron beam. The accelerator is equipped with a device for releasing the beam into the atmosphere. The electron energy of the beam is E = 1.4 MeV.

By the formula (1) calculate the surface density of the bulk (mass thickness) of the powder layer σ, resulting in a value in the range of 0.44 ... 0.55 g / cm ² . Select σ = 0.45 g / cm ² .

As the base metal for surfacing, structural steel 12XH3A is used. This type of steel is used for the production of products operating under high shock loads or at low temperatures.

A powder mixture of alloying and fluxing components is prepared. A powder mixture of alloying and fluxing components is applied to a large facet of a steel base measuring 12 × 50 × 100. Powders of chromium, nickel and titanium are introduced into the composition of the alloying component in a ratio that ensures the formation of a layer identical in composition to 12X18H10T stainless steel (Table 1).

The powder mixture is evenly distributed over the surface of the processed material, after which the base with a layer of powder is mounted on a movable table and moved in the direction of the length of the sample. The electron beam is scanned over the surface of the sample with a frequency of 50 Hz. The scanning span is set equal to 50 mm, so that it matches the width of the steel substrate, and the length of the surfacing strip is unlimited and is determined by the length of the substrate. In the case of surfacing on the basis of a larger width, surfacing is carried out by the formation of several strips, while the surfacing strip is joined to each other with an overlap of 5 mm. It is established experimentally that when the accelerating electron voltage in the beam is 1.4 MeV, the bulk thickness of the powder material is 0.45 g / cm ² , and the beam scanning width is 50 mm, surfacing at a beam current of 24 mA is optimal (corresponds to a beam power of 33.4 kW ) and the speed of movement of the workpiece under a beam of 10 mm / s.

To achieve the required concentration of alloying elements in the deposited layer, the surfacing of the powder mixture is repeated twice under the same conditions.

The results of x-ray spectral analysis of the composition of the deposited layer are presented in table 2.

A layer is formed on the surface of the steel base, the thickness of which reaches 2 ... 2.5 mm. The microstructure of the deposited layer is shown in FIG. 1. As a result of metallographic analysis of pores and microcracks were not found.

Using the X-ray diffraction method, it was found that the main phase in the coatings deposited by the electron beam is a γ-solid solution based on Ni, Fe. FIG. Figure 2 shows the phase composition of the layer formed during surfacing of the Fe-Cr-Ni-Ti powder mixture.

Tests for corrosion resistance in concentrated nitric acid (65%) at 125 ° C showed that the corrosion rate of the base material (12XH3A) is 1425 mm / year. The surfacing of the Fe-Cr-Ni-Ti powder mixture leads to a significant decrease in the corrosion rate to 0.61 mm / year. In a solution of concentrated (65%) orthophosphoric acid heated to 100 ° C, the corrosion rate on 12KHN3A steel plates is 2276 mm / year. When testing the deposited material, there is a significant decrease in the dissolution rate to 0.22 mm / year.

According to tests for adhesive strength, the level of bond strength of the layers reaches 526 MPa. The results obtained indicate the high quality of the materials obtained.

To assess the operational stability of the deposited layers at low temperatures, impact tests were carried out at a temperature of -60 ° C. Test results showed that the toughness (KCU- _60c) of the base metal is 67 J / cm ^2, and the deposited layer - 98 J / cm ^2. The presence of austenite with high ductility in the structure provides high resistance to fracture of the material under dynamic conditions.

Example 2. The formation of anti-corrosion coatings of identical steel grade 10X17H13M2T

The source of the relativistic electron beam is an industrial electron accelerator of the ELV-6 brand, which generates a beam with electron energy E = 1.4 MeV and is equipped with a device for releasing the beam into the atmosphere.

The base for surfacing is made of low carbon steel 10 with a size of 12 × 50 × 100 mm. A powder mixture is prepared from alloying and fluxing components in compliance with the ratio of alloying elements equal to their ratio in steel 10X17H13M2T, which should be obtained in the deposited layer. The composition of the surfacing mixture is shown in table 3.

By the formula (1) determine the acceptable range of density values of the filling (mass thickness) of the powder mixture on the surface of the substrate: 0.44 ... 0.55 g / cm ² . A layer of a powder mixture with a mass thickness of 0.45 g / cm ² is applied to a large face of the steel base. The powder mixture is evenly distributed over the surface of the processed material, after which the base with a layer of powder is mounted on a movable table and moved in the direction of the length of the sample. The electron beam is scanned over the surface of the workpiece with a frequency of 50 Hz and a scan range equal to the width of the workpiece - 50 mm. The length of the processing strip is unlimited and is determined by the length of the workpiece. In the case of surfacing on larger workpieces, surfacing is carried out by forming several strips, while the surfacing strips are joined to each other with an overlap of 5 mm. It is established experimentally that with the indicated processing parameters, the optimum mode is surfacing at a beam current of 24 mA (corresponds to a beam power of 33.4 kW) and a workpiece moving speed under the beam of 10 mm / s.

To achieve the required concentration of alloying elements in the deposited layer, the surfacing of the powder mixture on the surface of the workpiece is repeated twice under the same conditions.

The chemical composition of the deposited coating is determined by the results of x-ray spectral analysis. In FIG. 3 shows the microsection area on which the analysis was performed, and in FIG. 4 - averaged energy spectrum obtained by the analyzer. The results of determining the chemical composition of the deposited layer are presented in table 4.

A layer is formed on the surface of the workpiece, the thickness of which is 2 ... 2.5 mm. The microstructure of the deposited layer is shown in FIG. 5. As a result of metallographic analysis of pores and microcracks were not found.

By the method of x-ray diffraction (Fig. 6) it was found that the deposited layer consists of one phase of an γ-solid solution based on Fe, Cr, Ni. Thus, both the chemical composition and the phase composition of the deposited layer coincide with the similar characteristics of 10Kh17N13M2T steel.

Example 3. The formation of anti-corrosion coatings of identical steel grade 06X23N28M3D3T

As a source of a relativistic electron beam, an ELV-6 industrial electron accelerator is used, generating a beam with an electron energy of E = 1.4 MeV, equipped with a device for releasing the beam into the atmosphere.

The base for surfacing is made of low-carbon steel 10. A powder mixture of alloying and flux components is applied to a steel base with a size of 12 × 50 × 100 mm. Powders of chromium, nickel, molybdenum, copper and titanium are introduced into the alloying component in a ratio that ensures the formation of a layer identical in composition to 06Kh23N28M3D3T stainless steel, the flux component is formed from a mixture of fluoride salts CaF ₂ and LiF (Table 5).

By the formula (1) determine the acceptable range of density values of the filling (mass thickness) of the powder mixture on the surface of the substrate: 0.44 ... 0.55 g / cm ² . On a larger surface of the steel base, the layer of the powder mixture is evenly distributed with a mass thickness of 0.55 g / cm ² , after which the base with the powder layer is mounted on a movable table and moved in the direction of the length of the sample. The electron beam is scanned over the surface of the sample with a frequency of 50 Hz and a scan span equal to the workpiece width of 50 mm. The length of the processing strip is unlimited and is determined by the length of the workpiece. In the case of surfacing on larger workpieces, surfacing is carried out by forming several strips, while the surfacing strips are joined to each other with an overlap of 5 mm. It is established experimentally that with the specified processing parameters, the optimum mode is surfacing at a beam current of 24 mA (corresponds to a beam power of 33.4 kW) and a workpiece moving speed under the beam of 10 mm / s.

To achieve the required concentration of alloying elements in the deposited layer, the surfacing of the powder mixture on the surface of the workpiece is repeated twice under the same conditions.

The chemical composition of the deposited coating is determined by the results of x-ray spectral analysis. In FIG. 7 shows the microsection area on which the analysis was performed, and in FIG. 8 - averaged energy spectrum obtained by the analyzer. The results of determining the chemical composition of the deposited layer are presented in table 6.

A layer is formed on the surface of the sheet, the thickness of which is 2 ... 2.5 μm. The microstructure of the deposited layer is shown in FIG. 9. As a result of metallographic analysis of pores and microcracks were not found.

By the method of x-ray diffraction (Fig. 10) it was found that the deposited layer consists of a single phase of an γ-solid solution based on Fe, Cr, Ni. Thus, both the chemical composition and the phase composition of the deposited layer coincide with similar characteristics of 06Kh23N28M3D3T steel.

Example 4. The formation of a corrosion-resistant coating by surfacing a plate of an alloy containing alloying components in a ratio that ensures the formation on a steel base of a layer identical in composition to steel grade 06Kh23N28M3D3T.

As a source of a relativistic electron beam, an ELV-6 industrial electron accelerator is used, generating a beam with an electron energy of E = 1.4 MeV, equipped with a device for releasing the beam into the atmosphere.

The base for surfacing is made of low-carbon steel 10. A prefabricated plate with a thickness of 1.5 mm is placed on a steel billet with a size of 18 × 50 × 100 mm, with dimensions coinciding with the dimensions of the deposited surface of the base. The ratio of the constituent elements in the weld plate is chosen equal to the ratio of the alloying elements in the formed steel grade. The chemical composition of the plate material, presented in table 7, provides after surfacing the formation on the base surface of a layer of stainless steel grade 06X23N28M3D3T. Do not use flux during surfacing, since protection against weathering is due to the self-fluxing properties of nickel and chromium included in the plate.

The base with the plate placed on it is mounted on a movable table and moved in the direction of the length of the sample. The electron beam is scanned over the surface of the deposited plate with a frequency of 50 Hz. The scan range provides a surfacing width of 50 mm equal to the width of the workpiece, and the length of the surfacing strip can be unlimited and is determined by the length of the workpiece. In the case of surfacing on large workpieces, surfacing is carried out by forming several strips, while the surfacing strips are joined to each other with an overlap of 5 mm. It is established experimentally that with the specified processing parameters, the optimum mode is surfacing at a beam current of 24 mA (corresponds to a beam power of 33.4 kW) and a workpiece moving speed under the beam of 10 mm / s. The thickness of the formed stainless steel layer is 2.5 mm. The appearance of the sample after deposition of the plate is shown in FIG. 11. A closeup of the cross section of the sample is shown in FIG. 12.

The chemical composition of the deposited coating is determined by the results of x-ray spectral analysis (table 8).

As a result of metallographic analysis, no pores and microcracks were found in the deposited layer. By the method of X-ray diffraction (Fig. 13) it was found that the deposited layer consists of one phase of an γ-solid solution based on Fe, Cr, Ni.

Thus, both the chemical composition and the phase composition of the deposited layer coincide with similar characteristics of 06Kh23N28M3D3T steel.

Example 5. The formation of a corrosion-resistant coating of identical steel grade 10X17H13M2T in an inert gas at atmospheric pressure

An ELV-6 industrial electron accelerator is used as a source of a relativistic electron beam, generating a beam with an electron energy of E = 1.4 MeV and equipped with a device for releasing the beam into the atmosphere. The beam released from the exhaust device is introduced into a chamber filled with argon through an opening with a diameter of 6 mm [Report on the implementation of applied research by the grant of the Ministry of Education and Science, project code RFMEFI60414X0135, stage 1, page 317, stage 2, page 368]. A constant flow of argon is organized into the argon chamber in order to prevent air from entering the atmosphere. Inside the argon chamber at the place of beam entry, an electromagnetic scanning device is placed that provides scanning of the beam.

The base for surfacing is made of low carbon steel 10 with a size of 12 × 50 × 100 mm. A powder mixture is prepared consisting only of alloying elements without a flux component, observing the ratio of alloying elements equal to their ratio in 10Kh17N13M2T steel, which should be obtained in the deposited layer. The composition of the surfacing mixture is shown in table 9.

By the formula (1) determine the acceptable range of density values of the filling (mass thickness) of the powder mixture on the surface of the substrate: 0.44 ... 0.55 g / cm ² . A layer of powder mixture with a mass thickness of 0.55 g / cm ² is applied to a large facet of the steel base. The powder mixture is evenly distributed on the surface of the processed material, after which the workpiece is placed through a hatch in an argon chamber on a movable table located inside the chamber. Close the hatch and fill the chamber with argon. The table is moved in the direction of the length of the workpiece, the electron beam is scanned along the surface of the sample with a frequency of 50 Hz and the scan range equal to the width of the workpiece is 50 mm. The length of the surfacing strip is unlimited and is determined by the length of the workpiece.

It is established experimentally that with the specified processing parameters, the optimum mode is surfacing at a beam current of 24 mA (corresponds to a beam power of 33.4 kW) and a workpiece moving speed under the beam of 10 mm / s.

Unlike surfacing in an air atmosphere, to achieve the required concentration of alloying elements in the deposited layer, it is sufficient to conduct a single surfacing of the powder mixture on the surface of the workpiece.

The chemical composition of the deposited coating is determined by the results of x-ray spectral analysis. In FIG. 14 shows the microsection area on which the analysis was performed, and FIG. 15 - averaged energy spectrum obtained by the analyzer. The results of determining the chemical composition of the deposited layer are presented in table 10.

A layer is formed on the surface of the sheet, the thickness of which is 2 mm. As a result of metallographic analysis of pores and microcracks were not found. By the method of x-ray diffraction (Fig. 16) it was found that the deposited layer consists of one phase of a γ-solid solution based on Fe, Cr, Ni. Thus, both the chemical composition and the phase composition of the deposited layer coincide with the similar characteristics of 10Kh17N13M2T steel.

Claims (9)

1. The method of forming a corrosion-resistant coating of stainless steel on a low-carbon steel product, comprising placing on the surface of the workpiece a mixture of flux and powder powders containing alloying elements in a ratio that provides the specified composition of the stainless steel coating, and conducting electron beam welding of the deposited mixture by relativistic electron beam, and the total mass thickness of the powder layer placed on the surface, including flux and containing alloying elements was guides, is determined by the formula: σ = K⋅ (Е-b), where σ is the mass thickness of the deposited powder [g⋅cm ^-2 ], K = 0.4 ... 0.5 [g⋅cm ^-2 ⋅ MeV ^-1 ], E is the electron energy in the beam [MeV], b = 0, 3 [MeV]. 2. The method according to p. 1, characterized in that the salts CaF ₂ , LiF, MgF ₂ are introduced into the composition of the deposited mixture of powders as a fluxing component that provides protection from weathering. 3. The method according to p. 1, characterized in that the deposited on the product anti-corrosion coating, if necessary, is subjected to heat treatment to fix the austenitic phase. 4. The method according to p. 1, characterized in that the surfacing is carried out at an electron energy in the beam of at least 1 MeV. 5. The method according to p. 1, characterized in that the electron beam is removed into an inert gas medium at atmospheric pressure. 6. The method according to p. 1, characterized in that the surfacing on the treated surface is repeated many times depending on the required concentration of alloying elements in the deposited layer and its thickness. 7. A method of forming a corrosion-resistant coating of stainless steel on a low-carbon steel product, comprising placing on the surface of the workpiece a plate prefabricated from an alloy containing alloying elements in a ratio sufficient to provide an anti-corrosion coating corresponding to the required composition after surfacing stainless steel, and conducting electron beam surfacing with a relativistic electron beam, Weather resistance during surfacing is ensured by the self-fluxing properties of the elements contained in the plate.

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