RU2697757C1 - Method for dry local electropolishing blisk blades and working container for its implementation - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: invention relates to electropolishing of complex shape parts. Method comprises fastening blisk on holder, dipping blisk blades into electroconductive porous granules, filling working container, made from sulphonated copolymer of styrene-divinyl benzene and filled with electrolyte, connecting blisk to anode, and electroconductive granules to the cathode and polishing to produce the specified roughness of blisk blades surface. Working container used is an elastic cover from electrically insulating material with an electrode located inside, elastic cover is put on the treated blade, the elastic cover is filled with electroconductive granules, the granules are brought into vibration motion and back-and-forth movement along the back and trough of blade, which provide for uniform washing with back and trough blades granules. Working container is made from elastic electrically insulating material in the form of a jacket with dimensions and shape ensuring coverage of the entire treated surface of the blisk blade and its placement in the inter-blade space.

EFFECT: invention can be used in turbomachine building during blisk blades processing of gas turbine compressors.

12 cl, 5 dwg

Description

The invention relates to the technology of electropolishing of parts of complex shape and can be used in turbomachinery when processing blades 6 of the face of compressors of gas turbine engines, to provide the necessary physical, mechanical and operational properties of parts of turbomachines, and also as a preparatory operation before ion implantation modification of the surface of the part and application protective ion-plasma coatings.

The working blades of the compressor of a gas turbine engine (GTE) during operation are exposed to significant dynamic and static loads, as well as erosive destruction. Based on the requirements for operational properties, titanium alloys are used for the manufacture of gas turbine compressor blades, which, in comparison with technical titanium, have higher strength, including at high temperatures, while maintaining a sufficiently high ductility and corrosion resistance.

However, turbine blades are highly sensitive to voltage concentrators. Therefore, the defects formed in the manufacturing process of these parts are unacceptable, since they cause the occurrence of intense destruction processes. This causes problems when machining surfaces of turbomachine parts. In this regard, the development of methods for producing high-quality surfaces of turbomachine parts is a very urgent task.

The most promising methods for processing turbomachine blades are electrochemical methods of polishing surfaces [Griliches S.Ya. Electrochemical and chemical polishing: Theory and practice. Effect on the properties of metals. L., Mashinostroenie, 1987.], while the methods of electrolyte-plasma polishing (EPP) of the details are of the greatest interest for the field under consideration [for example, Patent GDR (DD) No. 238074 (A1), IPC C25F 3/16, publ. 08/06/86., As well as Patent RB No. 1132, IPC C25F 3/16, 1996, BI No. 3].

A known method of polishing metal surfaces, including anodic processing in an electrolyte [RB Patent No. 1132, IPC C25F 3/16, 1996, BI No. 3], as well as an electrochemical polishing method [US Patent No. 5028304, IPC B23H 3/08, C25F 3 / 16, C25F 5/00, publ. 07/02/91.]

Known methods of electrochemical polishing do not allow high-quality polishing of the surface of blades of blisk.

There is also a method of electrolyte-plasma polishing of parts made of titanium alloys [RF Patent No. 2373306, IPC C25F 3/16. The method of multi-stage electrolyte-plasma polishing of products from titanium and titanium alloys. Bull. No. 32, 2009], which includes immersing the part in an electrolyte containing an oxidizing agent, a fluorine-containing compound and water, forming a gas-vapor shell around the workpiece surface and igniting a discharge between the workpiece and the electrolyte by applying an electric potential to the workpiece.

However, the known method [RF Patent No. 2373306, IPC C25F 3/16] is multi-stage, which leads, on the one hand, to an increase in the complexity of the processing of parts, a decrease in the quality and reliability of the processing process due to the need to provide more process parameters and their ratios, and also to increase its complexity.

The closest technical solution to the claimed method is a method of ion polishing a metal part, which consists in filling the working container of the installation with electrically conductive granules, made of electrically conductive material, fixing the part on the holder, immersing the part in electrically conductive granules filling the container, connecting the part to the anode, and the container to cathode. [WO 2017186992 - | Method for smoothing and polishing metals via ion transport by means of free solid bodies, and solid bodies for carrying out said method. Publ. 2017.11.02].

However, the known method [WO 2017186992] does not allow to ensure high quality of the surface of the part due to the uneven interaction of the granules with the treated surface of the blades of blisk.

In addition, the prototype method [WO 2017186992] cannot be applied to the processing of blisk, having large dimensions, since when processing products having a significant surface area, an excessive amount of heat is generated, which makes the process unstable and leads to defects on the surface of the blades of blisk. At the same time, the processing of large products, which include blades of a gas turbine compressor, requires a significant amount of electricity and, when the polishing process is implemented under these conditions, the efficiency decreases sharply. processing.

The closest technical solution to the claimed device is a working container for electropolishing blades of blisk including a working container made of electrically conductive material [WO 2017186992 - | Methodforsmoothingandpolishingmetalsviaiontransportbymeansoffreesolidbodies, andsolidbodiesforcarryingoutsaidmethod. Publ. 2017.11.02].

However, this device [WO 2017186992] cannot be applied to the processing of blades of blisk, having large dimensions, since when processing products having a significant surface area, an excessive amount of heat is generated, which makes the process unstable and leads to defects on the surface of the blades. In addition, the processing of large products, which include blades of a gas turbine compressor, requires a significant amount of electricity, and when the polishing process is implemented under these conditions, the efficiency decreases sharply. processing.

The task to which the invention is directed is to increase the reliability of the process of polishing blades of blisk, as well as the quality and uniformity of processing of their surface by ensuring uniform interaction of granules with the treated surface of the blade and reducing its simultaneously processed area

The technical result of the invention improves the reliability of the process of polishing blades of blisk, as well as the quality and uniformity of processing of their surface.

The technical result is achieved due to the fact that in the method of dry local electro-polishing of the blades of blisk, which includes fixing the blisk on the holder, immersing the blades of blisk in the electrically conductive granules filling the working container, connecting the blisk to the anode, and the electrically conductive granules to the cathode and polishing to obtain a given surface roughness blades of blisk, in contrast to the prototype, use an elastic cover made of an insulating material with an inside located at its edge as a working container with at least one electrode, wear the aforementioned elastic cover on at least one blisk blade to be processed, fill the elastic cover with electrically conductive granules, expanding it within the interscapular space between the blisk blade to be processed and two blisk blades adjacent on both sides of the blade, provide contact with all the polished surface of the treated blisk blades with electrically conductive granules, bring the electrically conductive granules into vibrational motion and reciprocating motion in the direction the phenomenon along the back and trough of the scapula, which ensures uniform washing of the back and trough of the scapula with electrically conductive granules, is applied to the blisk positive, and the negative electric potential is applied to the electrically conductive granules through the electrode of the elastic cover and the processing is carried out until the specified surface roughness of the blades is obtained, then the granules are removed from the said elastic cover, remove the elastic cover from the treated scapula, put it on the next scapula blade and repeat the specified cycle until complete processing in The blades of blisk come down.

In addition, the following methods are possible: they use an elastic cover with a feeder filled with electrically conductive granules and forming a single volume with an elastic cover, and filling the elastic cover with electrically conductive granules is done by reducing the volume of the feeder by compressing the latter; electrically conductive granules are brought into vibrational motion due to vibration of said elastic cover, and the reciprocating movement of electrically conductive granules in the direction along the back and trough of the blade is provided either by relative movement of the blisk and the elastic cover, or by compression and expansion of the feeder; spherical particles with a diameter of 0.4 to 1.2 mm or oval particles with a size of 0.3 to 1.4 mm are used as granules, electrically conductive granules; use porous granules from a material that provides pore filling with electrolyte without forming an electrolyte film on the outer surface of the granule; as the material of the granules, a sulfonated styrene-divinylbenzene copolymer is used; polishing is carried out in argon medium, and a blisk of a titanium alloy turbine is used as a blisk, and an aqueous solution of a mixture of NH4F and KF with an NH ₄ F content of 5 to 15 g / l and KF from 30 to 50 g / l

The technical result is achieved due to the fact that the working container for electropolishing blisk blades made of non-conductive material and containing in the internal working volume of at least one electrode connected to the cathode, unlike the prototype, the container is made of elastic material in the form of a cover, dimensions and shape, providing coverage with a working gap of the entire treated surface of the blades of the blisk and its placement in the interscapular space between two blades adjacent to the processed blade ami, as well as equipped with a feeder with electrically conductive granules, which allows, when reducing its volume, to transport electrically conductive granules into the working volume of the said cover.

In addition, the following additional element of the working container is possible: the elastic walls of the cover are made with zigzag bends forming pockets, inside which spring electrodes are placed, and the pockets provide closing of the electrodes when the cover walls are in free position and opening when the cover walls are stretched due to straightening of the corrugations; the feeder with electrically conductive granules is made with corrugated walls, providing a change in the volume of the feeder when they are stretched or compressed; the working container is equipped with an elastic sealing element that provides sealing of its cavity at the boundary of its contact with the surface of the treated blisk, and is also equipped with a vibrator and a device for reciprocating movement of the working container.

The essence of the proposed method, the possibility of its implementation and use are illustrated by the examples below.

The invention is illustrated by the following scheme. In FIG. 1-5 shows the process of electropolishing blisk blades and the device of an elastic cover (working container). In FIG. 1, FIG. 2 and FIG. Figure 3 shows a fragment of blisk with an elastic cover when it is worn on the blisk blade to be processed (Fig. 1a, Fig. 2a and Fig. 3a) and when expanding the elastic cover when filling it with electrically conductive granules (Fig. 1b, Fig. 2b and Fig. 3) . In FIG. 4 shows the process of filling an elastic cover with electrically conductive granules. In FIG. 5 shows the wall of an elastic cover with flexible electrodes; they contain: 1 - blisk; 2 - scapula blade; 3 - processed (current) blade blisk; 4 - working container (elastic case); 5 - electrically conductive granules; 6 electrode; 7 - feeder; 8 - pockets. (The double arrows indicate the reciprocating motion of the electrically conductive granules; the single arrows indicate the direction of motion of the electrically conductive granules from the feeder to the case.

The inventive method of electropolishing blades blisk is as follows (Fig. 1 and 2).

As a working container, an elastic cover 4 made of electrical insulating material with at least one electrode 6 located inside is used. An elastic cover 4 is put on the blade being machined 3 of blisk 1 (Fig. 1a, Fig. 2a and Fig. 3a), the elastic cover 4 is filled electrically conductive granules 5, expanding the elastic cover 4 within the interscapular space between the machined blade 3 of blisk 1 and two blades 2 of blisk 1 adjacent to both sides thereof (Fig. 1b, Fig. 2b and Fig. 3b). (If necessary, you can similarly wear elastic cover 4 on a larger number of blades). When filling the elastic cover 4 with electrically conductive granules 5 (Fig. 4), it is necessary to ensure that they completely cover the polished surface of the processed blade 3 of blisk 1. Filling the elastic cover 4 with electrically conductive granules 5 can be performed, for example, using a feeder 7, which allows for the transportation of electrically conductive pellets granules 5 in the working volume of the elastic cover 4 (Fig. 4). After filling the elastic cover 4 with electrically conductive granules 5 granules, one of the known methods, for example using a vibrator, is brought into vibrational motion. At the same time, the granules are given a reciprocating movement in the direction along the back and trough of the processed blade 3, which ensures uniform washing of the back and trough of the blade 3 by electrically conductive granules 5 of the blade 3, after which an electric current is applied to the blister from the anode and to the electrode of the elastic cover 4 from the cathode and the surface treatment begins blades 3 to obtain the desired roughness. In this case, the reciprocating motion of the electrically conductive granules 5 can be created due to the reciprocating movements of the elastic cover 4 or blisk 1. After the processing of the blades 3 from the elastic cover 4 remove the conductive granules 5, remove the cover 4 from the treated blade 3 and put on the next blisk blade 1 and repeat the specified processing cycle until all blisk blades are completely processed. In the process of polishing the current blade 3 blisk 1 provide reciprocating motion of the granules in the entire volume of the elastic cover 4.

When polishing each blade 2 blisk 1 use a working container 4 in the form of an elastic cover 4 made of non-conductive material and containing in the internal working volume of at least one electrode 6 connected to the cathode. The elastic cover 4, in size and shape, should provide coverage with the working gap of the entire machined surface of the blade 3 of blisk 1. In this case, the elastic cover 4 should be placed in the interscapular space between two blades 2 adjacent to the processed blade 3 (Fig. 3a). When filling the elastic cover 4 with electrically conductive granules 5, it should increase in volume and fill the specified interscapular space (Fig. 3b). The elastic cover 4 can also be equipped with a feeder 7 with electrically conductive granules 6, which allows reducing the volume of the feeder 7 to transport electrically conductive granules 5 into the working volume of the elastic cover 4 (Fig. 4).

The walls of the elastic cover 4 can be made with zigzag bends (Fig. 5), forming pockets 8, inside which spring electrodes 6 are placed, and the pockets 8 provide closing of the electrodes 6 with the free position of the walls of the elastic cover 4 (Fig. 5a) and their opening when stretching the walls of the elastic cover 4 due to the straightening of the corrugations (Fig. 5b). Spring electrodes 6, when expanding the elastic cover 4 should be deformed along with the walls of the elastic cover 4. When putting on the elastic cover 4, the spring electrodes 6 are in the pockets 8 and do not touch the surface of the bladed blade 3 blisk 1. After filling the elastic cover 4 with electrically conductive granules 5 spring electrodes 6 are opened by opening pockets 8 and come into contact with electrically conductive granules 5.

The polishing process can be carried out at a current density of 0.2-10 A / cm ² . As the electrically conductive granules 5, either spherical particles with a diameter of 0.4 to 1.2 mm, or oval particles with a size of 0.3 to 1.4 mm, as well as porous granules 5 of a material that provides filling of pores with an electrolyte without formation can be used electrolyte films on the outer surface of granule 5, for example granules 5 made of a sulfonated styrene-divinylbenzene copolymer. Polishing can be carried out in an argon atmosphere, especially when polishing parts made of titanium and titanium alloys, in particular blades of blisk 2 of a turbine. When polishing blisk 1 from a titanium alloy, an aqueous solution of a mixture of NH ₄ F and KF can be used as an electrolyte with an NH ₄ F content of 5 to 15 g / l and KF of 30 to 50 g / l. In addition, during the polishing process, an additional relative movement of the processed blisk 1 and the working container (elastic cover) 4 can be made in the modes of reciprocating motion. The polishing process is carried out to obtain a given value of the surface roughness of the blades of blisk 1.

The reciprocating motion of the electrically conductive granules 5 can provide a uniform effect on the entire machined surface of the current blade 3 and thereby improve the quality and uniformity of its surface. In addition, due to the creation of homogeneous conditions for the entire volume of granules, a uniform flow of electrical processes is ensured, in particular, ion transfer during blade processing.

When implementing the method, the following processes occur. When the granules reciprocate, they collide with the workpiece surface. In this case, collisions between granules also occur in the entire volume of the working container, thus creating uniform conditions for the flow of electrical processes for the entire volume of granules. In this case, electrical processes between the part (anode) and granules (cathode) occur due to the contact of the mass of electrically conductive granules with each other and with the negative potential of the working container and / or the electrodes (cathodes) introduced into the mass of granules that are at a negative potential. In the collision of granules with microprotrusions on the workpiece surface, ionic ablation of the mass from microprotrusions occurs, as a result of which the surface is leveled, its roughness decreases and surface polishing occurs.

Example. Blisk blades of VT9 grade titanium alloy were subjected to treatment. The blisk blades to be processed were successively immersed in a working container with porous spherical granules from 0.6 to 0.8 mm in size, made of a sulfonated styrene-divinylbenzene copolymer. An aqueous solution of a mixture of NH ₄ F and KF with an NH ₄ F content of 6 g / L and KF of 33 g / L was used as an electrolyte-filler of granules. A positive voltage was applied to the part, and a negative voltage was applied to the granules (through spring electrodes located inside the walls of the elastic cover). The polishing process was carried out with continuous oscillatory motion of granules with an amplitude of 14 kHz. The polishing process was carried out at a current density of 1.8 A / cm ² .

The processing conditions of the prototype method [WO 2017186992] were as follows. The interaction of blades of blisk and granules due to the rotation of blisk in the volume of granules. The blades being processed immersed a working container with porous spherical granules from 0.6 to 0.8 mm in size, made of a sulfonated styrene-divinylbenzene copolymer. The working container ensured that all blisk blades were immersed in granules at once. An aqueous solution of a mixture of NH ₄ F and KF with an NH ₄ F content of 6 g / L and KF of 33 g / L was used as an electrolyte-filler of granules. A positive voltage was applied to the part, and a negative voltage was applied to the granules (through the container body). The polishing process was carried out at a current density of 1.8 A / cm ² .

Roughness values were compared in different parts of the part after the compared processing methods. The initial surface roughness of the parts was Ra 0.72 μm. After processing, the dispersion of roughness in different parts of the surface of the machined parts was: for the prototype from Ra 0.16 μm to Ra 0, 32 μm, for processed according to the proposed method from Ra 0.12 μm to Ra 0, 16 μm. In addition, when processing by the prototype method, overheating of the granules and blisk medium was observed due to the need to use more energy, since the processing area in this case was significantly larger than by the proposed method.

In addition, studies were carried out on the following modes of processing parts made of titanium alloy (VT-1, VT3-1, VT8). A processing mode giving a scatter of roughness values on the surface of the part of more than ΔRa 0.05 μm was taken as a negative result. The reciprocating motion of the granules is a satisfactory result (U.R.), providing only friction of the granules on the surface of the workpiece with its full immersion unsatisfactory result (N.R.).

The size and shape of the granules: spherical particles with a diameter of 0.2 mm (N.R.), 0.4 mm (U.R.), 0.6 mm (U.R.), 0.8 mm (U.R .), 1.2 mm (U.R.), 0, 14 mm (N.R.). Oval particles ranging in size from 0.3 to 1.4 mm. 0.2 mm (N.R.), 0.3 mm (U.R.), 0.5 mm (U.R.), 0.8 mm (U.R.), 1.2 mm (U .R.), 1.4 mm (U.R.), 0, 16 mm (N.R.).

Thus, the proposed method for dry local electropolishing of blades of blisk and the working container for implementing the method can improve the reliability of the process of polishing blades of blisk, as well as the quality and uniformity of processing of their surface by ensuring uniform interaction of granules with the treated surface of the blade and reducing its simultaneously processed area.

Claims (12)

1. A method of dry local electro-polishing of blaze blades, including fixing the blaze on the holder, immersing blaze of blisk in electrically conductive porous granules filling a working container made of styrene-divinyl benzene sulfonated copolymer and filled with electrolyte, connecting the blisk to the anode, and the conductive granules to the cathode and polishing to obtain a given surface roughness of the blades of blisk, characterized in that the working container is used in the form of an elastic cover made of electrical insulation material with at least one electrode located inside, wear said elastic cover on at least one blisk blade to be processed, fill the elastic cover with electrically conductive granules, expanding it within the interscapular space between the blisk blade to be processed and two blisk blades adjacent to both sides the contact of the entire polished surface of the treated blisk blade with electrically conductive granules, leads the electrically conductive granules to vibrate and the reciprocating movement in the direction along the back and trough of the scapula, providing uniform washing by the electrically conductive granules of the back and trough of the scapula, is applied to the blisk positive, and the negative electric potential is applied to the electrically conductive granules through the electrode of the elastic cover and the processing is carried out until the specified surface roughness of the scapula blade is obtained, then remove the granules from the said elastic cover, remove the elastic cover from the treated blade, put it on the next blisk blade and repeat by said ring to complete the processing of all the blades blisks. 2. The method according to p. 1, characterized in that they use an elastic cover with a feeder filled with electrically conductive granules and forming a single volume with an elastic cover, and filling the elastic cover with electrically conductive granules is done by reducing the volume of the feeder by compressing the latter. 3. The method according to claim 2, characterized in that the electrically conductive granules are vibrated by vibration of said elastic cover, and the reciprocating movement of the electrically conductive granules in the direction along the back and trough of the blade is provided either by relative movement of the blisk and the elastic cover, or by compression and unloading the feeder. 4. The method according to any one of paragraphs. 1-3, characterized in that as electrically conductive granules use spherical particles with a diameter of from 0.4 to 1.2 mm 5. The method according to any one of paragraphs. 1-3, characterized in that as the electrically conductive granules use oval particles with sizes from 0.3 to 1.4 mm 6. The method according to p. 4 or 5, characterized in that the use of porous granules from a material that provides filling the pores with electrolyte without forming an electrolyte film on the outer surface of the granules. 7. The method according to p. 6, characterized in that the polishing is carried out in argon medium, and a blisk of a turbine of titanium alloy is used as a blisk, and an aqueous solution of a mixture of NH ₄ F and KF with an NH ₄ F content of from 5 is used as an electrolyte up to 15 g / l and KF - from 30 to 50 g / l. 8. The method according to p. 1, characterized in that polishing is carried out in argon medium, and a blisk of a titanium alloy turbine is used as a blisk, and an aqueous solution of a mixture of NH ₄ F and KF with an NH ₄ F content of from 5 is used as an electrolyte up to 15 g / l and KF - from 30 to 50 g / l. 9. A working container for dry local electro-polishing of blades of blisk, made of non-conductive material, containing at least one electrode connected to the cathode in the internal working volume and filled with electrically conductive porous granules made of sulfonated styrene-divinyl benzene copolymer and filled with an electrolyte, characterized the fact that it is made of elastic material in the form of a cover with dimensions and shape that provide coverage with a working gap of the entire machined surface of the blade blisk and its placement in the interscapular space between two blades adjacent to the blade being machined, and is also equipped with a feeder with electrically conductive granules, which, when its volume is reduced, can transport electrically conductive granules to the working volume of the said cover. 10. The working container according to claim 9, characterized in that the elastic walls of the cover are made with zigzag bends forming pockets, inside which spring electrodes are placed, the pockets providing closing of the electrodes when the cover walls are in a free position and opening when the cover walls are stretched due to straightening corrugations. 11. The working container according to p. 9, characterized in that the feeder with electrically conductive granules is made with corrugated walls, providing a change in the volume of the feeder when they are stretched or compressed. 12. The working container according to any one of paragraphs. 9-11, characterized in that it is equipped with an elastic sealing element that provides sealing of the cavity at the boundary of its contact with the surface of the treated blisk, a vibrator and a device for reciprocating movement of the working container.

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