RU2573406C2 - Production of turbojet engine low-pressure compressor rotor shaft (versions) and turbojet engine low-pressure compressor rotor shaft (versions) - Google Patents

Abstract

FIELD: engines and pumps.

SUBSTANCE: turbojet engine low-pressure compressor rotor shaft represents a drum-disc design composed of a four-stage, hence, four-disc structure. The shaft is made in three steps. At the first stage, the assembly units, i.e. the shaft front and rear bearing journals, discs and spacers. At the second stage, said unit are assembled to three mounting sections to be coupled to compose the rotor shaft. Every section is a non-separable structure. The rotor shaft front bearing journal, first stage disc, second stage disc and spacer are fitted in the first section and coupled therein. The second section comprises the third stage disc with the rotor shaft rear gearing journal and spacer permanently jointed thereto. The third section makes the fourth stage disc. At the third stage, mounting sections are coupled via the spacers to complete the rotor shaft assembly at articulation of the second section spacer with the third section. The discs of all stages are composed of a single-piece element including the rim changing into a circular web with the hub provided with the central bore. Said rim is inscribed in the conditional surface of truncated cone diverging in working fluid flow direction with intermediate radius at the disc web conditional plane equal to design radius of the engine setting inner outline in said section if measured from the shaft axis to the rim outer surface. Rim of every disc has grooves for rotor vanes to be uniformly distributed over the edges and inclined to the shaft axis. The amount and frequency of grooves location are increased in direction of working fluid flow from disc to disc, from the first and third section. Besides, the groove lengthwise axes are located in the disc rotor at claimed angular frequency Y = (9.5÷14.8) [unit/rad] and inclination to the rotor axis in the projection on the arbitrary axial plane, perpendicular, to the radius drawn through the groove axis central point.

EFFECT: perfected manufacture parameters, higher efficiency and gas dynamic stability, longer rotor shaft life without increase in the input of material.

12 cl, 2 dwg

Description

The group of inventions relates to the field of aircraft engine manufacturing, namely to low-pressure compressors of aircraft turbojet engines, in particular to a method for manufacturing a rotor shaft of a low-pressure compressor.

Known axial compressor of the engine, containing a stator with vanes of straightening apparatuses and a rotor of a drum-disk type, including individual impellers. Each impeller is equipped with two disks arranged sequentially downstream in the longitudinal plane of the cross section of the drum. Both disks are interconnected by means of an annular collar of the first disk and a landing belt in the canvas of the second disk. The annular collar of the second disk forms a tract drum shell, acting as a spacer between the second and first disks of each subsequent working stage. On the rims of the wheels of the impellers, wedge-shaped annular recesses are made, which form an annular groove of the dovetail type for contact with wedge-shaped annular protrusions at the ends of the shelves of the blades (RU 2269678 C1, publ. 02.10.2006).

Known rotor shaft of a low pressure compressor (LPC), comprising a system of four disks, each of which contains a rim for installing and driving rotor blades, in communication with a shaft of a low pressure turbine (HPH) of a turbojet engine (turbojet engine) (N.N. Sirotin , AS Novikov, AG Paykin, AN Sirotin, Fundamentals of Designing the Production and Operation of Aircraft Gas Turbine Engines and Power Plants in the CALS Technologies System, Book 1. Moscow, Science 2011. pp. 249-259, 313 -317).

A known method of manufacturing the rotor shaft of the low pressure turbojet engine, in which the connection of the compressor disks to each other and to the structural elements of the rotor is performed using a flange connection or end slots. Alternatively, when assembling the rotor, the disks and trunnions are tightened either with one central bolt, or with several evenly distributed bolts, or the disks are joined by welding. Welding is performed at the junction of the joined disks (NN Sirotin, AS Novikov, AG Paykin, AN Sirotin. Fundamentals of designing the production and operation of aircraft gas turbine engines and power plants in the CALS technology system. Book 1 Moscow, Science 2011. p. 318-322).

The disadvantages of the known solutions include the lack of a system for selecting the set of necessary parameters of the disks forming the configuration of the rotor shaft and affecting the area of the flow section of the flow passage and placing grooves and blades on the disk rim that form the aerodynamic processes of interaction of the rotor shaft of the drum-disk structure with the flow of the working fluid, the lack of specification of the ranges of geometric and aerodynamic parameters of the spatial configuration of the disks and the angular orientation of the grooves in the cores of the disks, as well as the difficulty of obtaining a compromise combination of increased efficiency values, gas-dynamic stability (GDU) reserves of the compressor and, as a result, the difficulty of providing optimal dynamic strength and increased resource of the rotor shaft with a minimum of material consumption of the disks and their connections in the shaft structure.

The task of the group of inventions related by a single creative idea is to develop a method for performing the rotor shaft of the low pressure turbojet engine, as well as the rotor shaft assembled in this way with disks of improved aerodynamic configuration, spatial stiffness of the nodes and elements of the connection of the rotor shaft disks, providing forming discs and spacers, the shaft, the inner contour and the bore of the flowing part while improving the technological parameters of the production of KND necessary for higher Ia efficiency, dynamic stability and lifetime without increasing the consumption of materials compressor.

The task in terms of the method of manufacturing the rotor shaft of a low-pressure compressor of a turbojet engine is solved by the fact that the rotor shaft, according to the invention, is drum-disk, assembling a four-stage design in terms of the number of disks, and the shaft is manufactured in three stages; at the first stage, assembly units are made, including trunnions of the front and rear shaft bearings, discs and cylindrical spacers; at the second stage, the assembly units are assembled into three mounting sections, each of which is non-separable, while the first section is assembled from the engine entrance, sequentially connecting the axle of the front support of the rotor shaft, the disk of the first stage, the disk of the second stage and equipped with a cylindrical spacer, the second section includes a disk of the third stage, to which the trunnion of the rear support and the cylindrical spacer, equipped with a flange from the opposite end, are permanently attached, and the third sec tion is performed in the form of a disk of the fourth stage; at the third stage, these mounting sections are sequentially detachably connected through cylindrical spacers and complete the installation of the rotor shaft structure by releasably connecting the cylindrical spacer of the second section with the fourth-stage disk forming the third section; moreover, the disks of all steps of the rotor shaft of the low pressure rotor are made of stamped blanks in the form of a single element, including a rim turning into an annular web with a hub, which is made with a central hole, and the rim is inscribed in a conditional surface of a truncated cone, expanding in the direction of flow of the working fluid, with an intermediate radius in the average conditional plane of the blade web, equal to the design radius of the inner contour of the engine duct in the specified section, counting from the shaft axis to the outer surface of a, and the gradient G _4ob conical extension of the rim, which during the manufacture of the disc of the fourth stage in a range taking

where R _max and R _min - the maximum and minimum radii of the outer surface of the rim of the disk of the fourth stage, and In _about - the axial width of the rim of the disk of the fourth stage; the rim of each disk is provided with grooves designed for rotor blades, which are evenly distributed around the perimeter and are inclined to the axis of the shaft, and the number and frequency of the grooves are increased in the direction of flow of the working fluid from the disk to the disk from the first to the third section, including by placing the longitudinal axis of the grooves in the rim of the fourth-stage disk with an angular frequency of Y = (9.5 ÷ 14.8) [units / rad] and an inclination to the axis of the rotor in the projection onto the conditional axial plane normal to the radius drawn through the center point of the axis groove, angled m α, which take values in the range of α = (24 ÷ 30) °.

2. A method of manufacturing a rotor shaft of a low-pressure compressor of a turbojet engine according to claim 1, characterized in that during the machining of the disk of the first stage from the front side of the sheet and the disk of the third stage from the back side of the sheet, they are turned up to the design dimensions, located under the rim of the indicated of disks a cantilever annular conical element for subsequent connection when assembling a section with conical diaphragms of trunnions of the front and rear shaft bearings, while the length of the generatrix of these conical elements ntov not operate beyond the envelope of a corresponding disc flange and conical connection ring members and said disc aperture trunnions operate integrally; similarly, one-piece disks of the first and second steps are permanently connected by the rim shelves, they also attach the first intersection annular cylindrical spacer with a flange to the rear shelf of the second-stage disc, in which (36 ÷ 44) holes are made during the manufacturing process for subsequent releasable connection with the third-stage disc blade as a part the second section in the third final stage of manufacture of the rotor shaft.

The problem in part of the rotor shaft of a low-pressure compressor of a turbojet engine is solved by the fact that the rotor shaft, according to the invention, is made of a drum-disk, four-stage in the number of disks and made in the manner described above.

The problem in the part of the rotor shaft of a low-pressure compressor of a turbojet engine, comprising a housing with a flow part, is solved by the fact that the rotor shaft according to the invention contains three mounting sections, two of which are the first, for connecting the rotor shaft equipped with working blades in series and the second is made non-separable, while the first mounting section from the engine input includes a pin in series of the front support of the rotor shaft, a disk of the first stage, a disk of the second of the first stage and a cylindrical spacer equipped with a flange, the second section includes a disk of the third stage connected with an axle of the rear support of the rotor shaft and a cylindrical spacer equipped with a flange, and the third mounting section consists of a disk of the fourth stage, each disk of all stages of each of the mounting sections is made in the form of a single element, including a rim, turning into an annular web reinforced with a hub provided with a central hole, while the rim of each disk is provided with grooves that are evenly distributed along the perimeter and are made inclined to the axis of the shaft, and the longitudinal axis of each of the grooves of the fourth-stage disk as part of the third mounting section forms with the rotor axis projected onto a conditional axial plane normal to the radius drawn through the center point of the groove axis, an angle α defined in the range α = (24 ÷ 30) °, and the grooves are evenly spaced around the perimeter of the disk with an angular frequency of Y = (9.5 ÷ 14.8) [units / rad], while the fourth-stage disk rim as part of the third mounting section is made with increasing from the entrance to the exit of the section with a radius of grad radial expansion _factor G _4ob defined in the range

where R _max and R _min - the maximum and minimum radii of the outer surface of the rim of the disk of the fourth stage, and In _about - the axial width of the rim of the disk of the fourth stage.

Moreover, as part of the third mounting section, the fourth-stage disk rim can be symmetrically connected to the disk blade to form equal-shouldered annular shelves, and the disk blade can be removably connected to the disk shelf of the previous stage through a cylindrical spacer forming a cantilever ring shell, the radius of the disk from the axis of the rotor shaft to the outer surface of the rim in the middle plane of the disk web is (0.53 ÷ 0.79) from the radius of the peripheral contour of the engine flow passage.

The configuration of the cross-section of the grooves of the rim of each of the disks of the sections of the indicated set can be performed according to the dovetail type, while the fourth-stage disk as part of the third mounting section is made with a radial distance from the lower point of the hub to the outer surface of the disk rim of at least 1, 05 times greater than the radial distance in the light between the inner and peripheral contours of the lumen of the engine duct, in addition, sections of the outer surface between the grooves of the rims of the disks of all sections are made generatrix and an inner flow surface of the engine, a drive shaft of said rotor sections location area CPV, the wheel rim flange disks third and fourth steps consisting of the second and third mounting sections are each provided with an annular groove for fixing the shank of the rotor blades, the split ring elements.

The task in terms of the method of manufacturing the rotor shaft of a low-pressure compressor of a turbojet engine according to the second embodiment is solved by the fact that the rotor shaft, according to the invention, is made drum-disk, assembling a four-stage design in terms of the number of disks, and the shaft is manufactured in three stages; at the first stage, assembly units are made, including trunnions of the front and rear shaft bearings, discs and ring spacers, which are cylindrical; at the second stage, the assembly units are assembled into three mounting sections, each of which is non-separable, while the first section is assembled from the engine entrance, connecting the axle of the front support of the rotor shaft, the disk of the first stage, the disk of the second stage and equipped with a flange cylindrical spacer, the second section includes a disk of the third stage, to which the conical diaphragm of the axle of the rear support and the cylindrical spacer provided from the opposite end flange, and the third section operates as a disc of the fourth stage; at the third stage, the mounting sections are sequentially detachably connected through cylindrical spacers and complete the installation of the rotor shaft structure, releasably connecting the output spacer of the second mounting section with a fourth-stage disk forming the third shaft section; moreover, the disks of all steps of the rotor shaft of the low pressure rotor are made of stamped blanks in the form of a single element, including a rim turning into an annular web with a hub, which is made with a central hole, and the rim is inscribed in a conditional surface of a truncated cone, expanding in the direction of flow of the working fluid, with an intermediate radius in the average conditional plane of the blade web, equal to the design radius of the inner contour of the engine duct in the specified section, counting from the shaft axis to the outer surface of and, while the rim of each disk is provided with grooves that are evenly distributed around the perimeter and are inclined to the axis of the shaft, and the number and frequency of placement of the grooves increase in the direction of flow of the working fluid from the disk to the disk and from the first section to the third, including by placing the longitudinal axis of the grooves in the rim of the fourth-stage disk with an angular frequency of Y = (9.5 ÷ 14.8) [units / rad] and an inclination to the rotor axis in the projection onto the conditional axial plane normal to the radius drawn through the center point of the groove axis, at an angle α, which is taken in dia the range of values α = (24 ÷ 30) °, in addition, in the process of manufacturing the fourth-stage disk for the third mounting section, the rim is made with an external surface inscribed in a conditional truncated conical surface, with a slope of the surface forming in the axial plane of the rotor shaft at an angle φ = (1 ÷ 5) ° to the axis of the latter.

In the manufacture of the fourth-stage disk of the third mounting section of the shaft, the disk rim can be made with an inscribed outer surface in the conditional surface of a truncated cone radially increasing in the direction of flow of the working fluid with a gradient of conical expansion of the rim G _4ob , which is accepted in the range

where R _max and R _min - the maximum and minimum radii of the outer surface of the rim of the disk of the fourth stage, and In _about - the axial width of the rim of the fourth stage of the disk as part of the third mounting section.

The task in part of the rotor shaft of a low-pressure compressor of a turbojet engine according to the second embodiment is solved by the fact that the rotor shaft, according to the invention, is made of a drum-disk, four-stage in the number of disks and is made as described above.

The task of the second embodiment, in terms of the rotor shaft of a low-pressure compressor of a turbojet engine, including a housing with a flow part, is solved by the fact that the rotor shaft according to the invention contains three sections intended for series connection with the formation of the rotor shaft supplied with blades, two of which , the first and second, made non-separable, while the first section from the engine input includes a pin in series of the front support of the rotor shaft, a disk of the first stage, a disk of the second stage and a cylindrical spacer provided with a flange, the second drive section includes third stage, communicating with a cylindrical spacer provided with a flange, and the third is formed consisting of the disc of the fourth stage; moreover, each disk is made in the form of a single element, including a rim turning into an annular web reinforced with a hub provided with a central hole, and the rim of each of the said disks is provided from the side facing the flow part with a system of grooves for the lock located at an angle to the axis of the rotor shaft connection with the rotor blades, in addition, the generatrix of the outer surface of the rim of the fourth-stage disk as part of the third mounting section makes an angle φ = (1 ÷ 5) ° with the axis of the rotor shaft in the axial plane of the latter.

In this case, the longitudinal axis of each of the grooves of the fourth-stage disk as part of the third mounting section can form, with the rotor axis projected onto the conditional axial plane normal to the radius drawn through the center point of the groove axis, an angle α defined in the range of values α = (24 ÷ 30) °, and the grooves are evenly spaced around the perimeter of the disk with an angular frequency of Y = (9.5 ÷ 14.8) [units / rad], while the rim of the fourth-stage disk as part of the specified mounting section is made increasing from entrance to exit radius section with radial gradient G _4ob ext range defined

where R _max and R _min - the maximum and minimum radii of the outer surface of the rim of the disk of the fourth stage, and In _about - the axial width of the rim of the disk of the fourth stage as part of the third mounting section.

The configuration of the cross section of the grooves of the rim of each of the section disks can be performed according to the dovetail type, while the fourth-stage disk as part of the third mounting section is made with a radial distance from the lower point of the hub to the outer surface of the disk rim by at least 1.05 times large radial distance in the light between the inner and peripheral contours of the lumen of the engine duct, in addition, sections of the outer surface between the grooves of the rim of the disks of all sections are made forming the inner surface the flow part of the engine, in the area of the disks of the indicated sections of the rotor shaft of the CPV.

The technical result of the group of inventions related by a single creative idea is to improve the technological parameters of the production of KND necessary to increase efficiency, and to expand the supply of gas-dynamic stability in the full range of compressor operating modes by 2.2% while increasing the resource of the rotor shaft by 2 times without increasing the material consumption compressor.

The invention is illustrated by drawings, where:

in FIG. 1 shows a rotor shaft of a low-pressure compressor turbofan engine, a longitudinal section;

in FIG. 2 - a fragment of the rim of the disk of the fourth stage of the shaft of the rotor KND, side view.

In the method of manufacturing the rotor shaft of a low-pressure compressor of a turbojet engine, the rotor shaft is made drum-disk, assembling a four-stage design according to the number of disks 1, 2, 3, 4. The manufacture of the shaft is carried out in three stages.

At the first stage, assembly units are manufactured, including trunnions 5 and 6, respectively, of the front and rear shaft supports, disks 1, 2, 3, 4 and cylindrical spacers 7, 8.

In the second stage, the assembly units are assembled into three assembly sections forming a set. Each mounting section is non-separable. In the first from the engine entrance, the mounting section is mounted, sequentially connecting in the direction of the working fluid flow pin 5 of the front support of the rotor shaft, disk 1 of the first stage, disk 2 of the second stage and cylindrical spacer 7 equipped with a flange 9. The second section includes a disk 3 of the third stage , to which the axle 6 of the rear support of the rotor shaft and the cylindrical spacer 8, equipped with a flange 10 at the opposite end, are permanently connected. The third mounting section is made in the form of a disk 5 of the fourth stage.

At the third stage, these mounting sections are sequentially, releasably connected through cylindrical spacers 7, 8. Complete the installation of the rotor shaft structure by releasably connecting the cylindrical spacer 8 of the second mounting section with the fourth stage disk 4 forming the third section.

Disks 1, 2, 3, 4 of all the steps of the rotor shaft of the low pressure rotor are made of stamped blanks in the form of a single element, including a rim 11, passing into an annular web 12 with a hub 13 made with a Central hole 14.

The rim 11, the disk 4 of the first stage is made inscribed in the conditional surface of a truncated cone, expanding in the direction of flow of the working fluid, with an intermediate radius in the average conditional plane of the blade web 12 of the disk equal to the design radius of the internal contour of the engine duct in the indicated section, counting from the shaft axis to the outer surface 15 of the rim 11, and with a gradient of G _{4 about the} conical expansion of the rim 11, which, in the manufacturing process of the disk 4 of the fourth stage, take in the range

where R _max and R _min - the maximum and minimum radii of the outer surface of the rim of the disk of the fourth stage, and In _about - the axial width of the rim of the disk of the fourth stage;

The rim 11 of each disk 1, 2, 3, 4 is provided with slots 16 for rotor blades, which are evenly distributed around the perimeter and are inclined to the axis of the shaft. The number and frequency of the grooves are increased in the direction of flow of the working fluid from the disk 1 to the disk 4 from the first to the third section, including placing the longitudinal axis of the grooves 16 in the rim 11 of the fourth-stage disk 4 with an angular frequency Y = (9.5 ÷ 14, 8) [units / rad] and inclination to the rotor axis in the projection onto the conditional axial plane normal to the radius drawn through the center point of the groove axis at an angle α, which is taken in the range of values α = (24 ÷ 30) °.

In the process of machining the disk 1 of the first stage from the front side of the blade 11 and the disk 3 of the third stage from the back side of the blade 11 is turned up to the design dimensions, placing a cantilever ring conical element 17, 18 under the rim 11 of the said disks. Ring element 17 perform for subsequent connection when assembling the corresponding section with a conical diaphragm 19 of the pin 5 of the front shaft support. The annular element 18 is performed for subsequent connection when assembling the corresponding section with the conical diaphragm 20 of the pin 6 of the rear shaft support. The length of the generatrix of these conical elements 17, 18 is performed not extending beyond the envelope of the shelf of the corresponding disk 1, 3. The connection of the conical ring elements 17, 18 of the disk 1, 3 and the diaphragms 19, 20 of the pins 5, 6 is produced by electron beam welding. Also, the discs 1 and 2, respectively, of the first and second stages are permanently connected by the shelves of the rims 11.

Also, in welding, a first intersection annular cylindrical spacer 7 with a flange 9 is attached to the rear shelf 21 of the disk 2 of the second stage, in which, during the manufacturing process, holes (36 ÷ 44) are made for subsequent detachable connection, on the tightening bolts with the blade 12 of the disk 3 of the third stage in the composition of the second section at the third final stage of manufacture of the rotor shaft.

The rotor shaft of a low-pressure compressor of a turbojet engine is made drum-disk, four-stage in the number of disks 1, 2, 3, 4 and is made as described above.

The rotor shaft of a low-pressure compressor of a turbojet engine, comprising a housing with a flowing part, contains three sections intended for serial connection with the formation of the rotor shaft equipped with rotor blades 22.

The first and second mounting sections are non-separable. The first section from the engine entrance includes a pin 5 of the front support of the rotor shaft, a disk 1 of the first stage, a disk 2 of the second stage and a cylindrical spacer 7 provided with a flange 9. The second section includes a disk 3 of the third stage, in communication with the pin 6 of the rear support of the rotor shaft and a cylindrical spacer 8 provided with a flange 10. The third mounting section is made up of a fourth-stage disc 4.

Each disk 1, 2, 3, 4 of all stages of each of the mounting sections is made in the form of a single element, including a rim 11, turning into an annular web 12, reinforced by a hub 13, provided with a Central hole 14.

The rim 11 of each disk 1, 2, 3, 4 is provided with grooves 16 intended for rotor blades 22, which are evenly distributed around the perimeter and are inclined to the axis of the shaft. The longitudinal axis of each of the grooves 16, the fourth-stage disk 4 as part of the third mounting section forms, with the rotor axis, projected onto a conditional axial plane normal to the radius drawn through the center point of the groove 16 axis, an angle α defined in the range of α = (24 ÷ 30) °. The grooves 16 are evenly spaced around the perimeter of the disk with an angular frequency Y = (9.5 ÷ 14.8) [units / rad].

The rim 11 of the disk 4 of the fourth stage as part of the third mounting section is made with increasing radius from the entrance to the exit of the section with a gradient of radial expansion G _4ob defined in the range

where R _max and R _min - the maximum and minimum radii of the outer surface 15 of the rim 11 of the disk 4 of the fourth stage, and In _about - the axial width of the rim 11 of the disk 4 of the fourth stage.

As part of the third mounting section, the rim 11 of the fourth stage disk 4 is symmetrically connected to the blade sheet 12 of the disk 1 with the formation of equal shouldered annular shelves 23. The blade 12 of the disk 4 is removably connected to the rear shelf 24 of the disk 3 of the previous stage through a cylindrical spacer 8 forming a cantilever ring shell. The radius of the disk 4 from the axis of the rotor shaft to the outer surface 15 of the rim 11 in the middle plane of the blade 12 of the disk 4 is (0.53 ÷ 0.79) from the radius of the peripheral contour of the engine duct.

The configuration of the cross section of the grooves 16 of the rim 11 of each of the disks 1, 2, 3, 4 of the sections is made according to the dovetail type. The fourth stage disk 4 as part of the third mounting section is made with a radial distance from the lower point of the hub 13 to the outer surface 15 of the rim 11 of the disk 4 at least 1.05 times greater than the radial distance in the light between the inner and peripheral contours of the lumen of the engine duct. Sections of the outer surface 15 between the grooves 16 of the rim 11 of the disks 1, 2, 3, 4 of all sections are made forming the inner surface of the flowing part of the engine in the area of the disks of the indicated sections of the rotor shaft of the CPV. The front shelves of the rims 11 of the disks 3 and 4 of the third and fourth stages, respectively, as part of the second and third mounting sections are each equipped with an annular groove for fixing the shanks of 25 rotor blades 22, split ring elements (not shown in the drawings).

In the method of manufacturing the rotor shaft of the low-pressure compressor of the turbojet engine according to the second embodiment, the rotor shaft is made drum-disk, assembling a four-stage construction according to the number of disks 1, 2, 3, 4. The manufacture of the shaft is carried out in three stages.

At the first stage, assembly units are manufactured - axles 5 and 6, respectively, of the front and rear shaft supports, disks 1, 2, 3, 4 and annular cylindrical spacers 7, 8.

In the second stage, the assembly units are assembled into three mounting sections. Each mounting section is non-separable. In the first from the engine entrance, the mounting section is mounted, connecting in series in the direction of the working fluid flow pin 5 of the front rotor shaft support, the first stage disk 1, the second stage disk 2 and the cylindrical spacer 7 equipped with a flange 9. The third mounting disk 3 is included in the second mounting section steps, to which the conical diaphragm 20 of the pin 6 of the rear rotor shaft support and the cylindrical spacer 8, provided with a flange 10 from the opposite end, are permanently connected. The third mounting section is made in the form of a disk 4 of the fourth stupa no.

In the third stage, these mounting sections are sequentially detachably connected through the cylindrical spacers 7, 8. Complete the installation of the rotor shaft structure by releasably connecting the cylindrical spacer 8 of the second mounting section to the fourth stage disk 4 forming the third shaft section.

Disks 1, 2, 3, 4 of all stages of the rotor shaft of the low pressure rotor are made of stamped blanks in the form of a single element, including a rim 11, turning into an annular web 12 with a hub 13, which is made with a Central hole 14. The rim 11 is made inscribed in the conditional surface of the truncated cone , expanding in the direction of flow of the working fluid, with an intermediate radius in the average conditional plane of the blade web 12 of the disk, equal to the design radius of the internal contour of the engine duct in the specified section, counting from the axis of the shaft to the outer surface minute 15 of the rim 11.

The rim 11 of each disk is provided with grooves 16, which are evenly distributed around the perimeter and are inclined to the axis of the shaft. The number and frequency of the grooves 16 are increased in the direction of flow of the working fluid from the disk 1 to the disk 4 and from the first section to the third, including placing the longitudinal axis of the grooves 16 in the rim 11 of the fourth stage disk 4 with an angular frequency Y = (9.5 ÷ 14.8) [units / rad] and inclination to the axis of the rotor in the projection onto the conditional axial plane normal to the radius drawn through the central point of the axis of the groove 16 at an angle α, which is taken in the range of values α = (24 ÷ 30) ° .

In the manufacturing process of the fourth stage disk 4 for the third mounting section, the rim 11 is made with an external surface 15 inscribed in a conditionally truncated conical surface, with a slope of the surface of the specified surface in the axial plane of the rotor shaft at an angle φ = (1 ÷ 5) ° to the axis of the latter.

In the manufacture of a disk 4 of the fourth stage of the third mounting section of the shaft, the disk rim 11 is formed with an inscribed outer surface in the conditional surface of a truncated cone radially increasing in the direction of flow of the working fluid with a gradient of conical expansion of the rim G _4ob , which is accepted in the range

where R _max and R _min - the maximum and minimum radii of the outer surface of the rim of the disk of the fourth stage, and In _about - the axial width of the rim of the fourth stage of the disk as part of the third mounting section.

According to the second embodiment, the rotor shaft of the low-pressure compressor of a turbojet engine is made drum-disk, four-stage in the number of disks 1, 2, 3, 4 and is made as described above.

According to the second embodiment, the rotor shaft of a low-pressure compressor of a turbojet engine, including a housing with a flow part, contains three mounting sections for connecting in series with the formation of the rotor shaft provided with working blades 21. The first and second sections are non-separable. The first mounting section from the engine entrance includes a pin 5 of the front support of the rotor shaft, a disk 1 of the first stage, a disk 2 of the second stage and a cylindrical spacer 7 equipped with a flange 9. The second mounting section includes a disk 3 of the third stage, in communication with the pin 6 of the rear support the rotor shaft and a cylindrical spacer 8 provided with a flange 10. The third mounting section is made up of a disk 4 of the fourth stage.

Each disk 1, 2, 3, 4 is made in the form of a single element, including a rim 11, turning into an annular web 12, reinforced by a hub 13 provided with a central hole 14. The rim 11 of each disk 1, 2, 3, 4 is provided on the side facing the flow part, a system of grooves 16 arranged at an angle to the axis of the rotor shaft for locking connection with the rotor blades 22. The generatrix of the outer surface 15, the rim 11 of the disk 4 of the fourth stage as part of the third mounting section comprises an angle φ = (1 ÷ 5) ° with the axis of the rotor shaft in the axial plane of the latter.

The longitudinal axis of each of the grooves 16 of the disk 4 of the fourth stage as part of the third mounting section forms, with the axis of the rotor, projected onto a conditional axial plane normal to the radius drawn through the center point of the axis of the groove 16, an angle α defined in the range of values α = (24 ÷ 30) °. The grooves 16 are evenly spaced around the perimeter of the disk with an angular frequency Y = (9.5 ÷ 14.8) [units / rad].

The rim 11 of the disk 4 of the fourth stage as part of the third mounting section is made with increasing radius from the entrance to the exit from the section with a gradient G _{4 о} radial expansion, defined in the range

where R _max and R _min - the maximum and minimum radii of the outer surface of the rim of the disk of the fourth stage, and In _about - the axial width of the rim of the disk of the fourth stage as part of the third mounting section.

The cross-sectional configuration of the grooves 16 of the rim 11 of each of the section disks is made according to the dovetail type, the fourth stage disk 4 as part of the third mounting section is made with a radial distance from the lower point of the hub 13 to the outer surface 15 of the rim 11 of the disk 4, not less than 1.05 times greater than the radial distance in the light between the internal and peripheral contours of the lumen of the engine duct. The sections of the outer surface 15 between the grooves 16 of the rim 11 of the disks of all sections are made forming the inner surface of the flowing part of the engine in the area of the disks of the indicated sections of the rotor shaft of the CPV.

The manufactured disk of the first stage has the following geometric parameters: overall width of the hub - 34 mm; diameter of the central hole of the hub - 120 mm; average web thickness - 9 mm; rim width - 61 mm; input and output diameters of the outer surface of the disk rim - 364 mm and 415 mm; the angle of inclination of the generatrix of the outer surface of the rim of the disk is 21 °.

The manufactured disk of the second stage has the following geometric parameters: overall width of the hub - 30 mm; diameter of the central hole of the hub - 157 mm; average web thickness - 6 mm; rim width - 50 mm; input and output diameters of the outer surface of the rim of the disk - 464 mm and 491 mm; the angle of inclination of the generatrix of the outer surface of the rim of the disk is 15 °.

The manufactured disk of the third stage has the following geometric parameters: overall width of the hub - 25 mm; diameter of the central hole of the hub - 150 mm; average web thickness - 5 mm; rim width - 43 mm; input and output diameters of the outer surface of the disk rim - 509 mm and 517 mm; the angle of inclination of the generatrix of the outer surface of the rim of the disk is 5 °.

The manufactured disk of the fourth stage has the following geometric parameters: overall width of the hub - 28 mm; diameter of the central hole of the hub - 240 mm; average web thickness - 4 mm; rim width - 48 mm; input and output diameters of the outer surface of the disk rim - 524 mm and 528 mm; the angle of inclination of the generatrix of the outer surface of the rim of the disk is 2 °.

When the engine is started, the rotor shaft, which combines the disks of all stages, is driven by the torque transmitted from the high-pressure pump through the rim of the disks integrated into the drum-disk design of the rotor shaft of the low-pressure rotor and includes the blades of the impeller. As a result, the flow of the working fluid in the CPV is forced. At the same time, the KND rotor shaft ensures the stability of the design form and the position of the disks of all stages in the drum-disk structure at all possible modes of the turbojet engine due to the perception of the combination of loads that arise during the compressor operation, and transmits radial and axial through the conical ring elements 17, 27 loads on the rotor shaft bearings with less energy loss and lower vibrations.

The technical result of the invention is achieved by the combination of the design solutions and geometric parameters of the main elements of the rotor shaft of the low pressure turbojet engine, namely the radial parameters of the disks 1, 2, 3, 4, with the geometric configuration of the outer surface of the rim 11 of the shaft disks, forming the surface of the inner wall of the engine duct , the adopted combination of a thin web 12 and the axial width of the hub 13, compensating for the weakening of the web 12 of the disk by the Central hole 14, which leads to a decrease in material consumption and increasing the maximum allowable effort in the disc elements. The geometric parameters of the holes 14 in the hub 13 are accepted sufficient for free passage of the spline pipe during installation. The excess of the radius of the hole in the hub 13 by at least 10% relative to the radius of the spline pipe is necessary for the installation tool to be inserted into the compressor cavity during installation.

The technical result is provided by the geometric configuration of the disks 1, 2, 3, 4, namely, the input and output radii along the width of the rim 11 of the disk with the ratio of the radii, counting from the axis of the rotor shaft to the outer surface of the rim of the disk and with the angles of inclination of the rims forming the configuration of the said surface flowing part with smooth conjugation of the ends of adjacent disks. The technical result of the present invention is also provided by the claimed geometric configuration of the disk within the specified range of relations between the difference of the output and input radii to the width of the rim 11 of the disk 1 of the first stage. Yield gradient G _Ob outside the claimed range G _of = (0,034 ÷ 0,046) would lead to an unacceptable mismatch radial settings of input and output flow areas of the flow part of the fourth stage and the previous stages CPV not provide the necessary differences working fluid pressure in said stages CPV that as a result, it will lead to a decrease in the efficiency and reserves of the compressor gas compressor and the disk resource, as well as to an additional operational fuel consumption and increased engine wear. In addition, on the outer side of the rim 11 of the disks 1, 2, 3, 4, a pulling system is used to draw a system of grooves 16 evenly spaced around the perimeter of the disk to secure the blades. The grooves 16 are located at an angle to the axis of rotation of the rotor. The technical result of the invention is achieved by performing grooves located at an angle α taken within the range (24 ÷ 30) ° found in the invention, since it makes it possible to install the blades at an angle that creates the greatest pressure drop at the inlet and outlet of the working fluid stream from the impeller of the first stage of the KND rotor and the most favorable working conditions are created that increase the supply of gas turbine, efficiency and resource with minimal material consumption of the rotor shaft. The exit of the angle α values outside the declared range (24 ÷ 30) ° will lead to a significant reduction in the supply of hydraulic control gear for multi-mode compressor operation, a decrease in rotor efficiency and an increase in the risk of accidentally dangerous airflow disruption from the compressor rotor impeller blades 16 mounted in the grooves of the disk with the resulting loss of hydraulic control gear . With an increase in the angle α _о > 24 °, the deviations of the axis of the groove 16 of the disk 4 from the axis of rotation of the rotor unjustifiably increase the voltage in the blades of the impellers at all operating modes of the low pressure switch, which leads to a decrease in the resource of the disk-blade-wreath system, an increase in material consumption, and the compressor becomes heavier and decrease in operational efficiency of the engine. In addition, the grooves 16 are evenly spaced around the perimeter of the disk 4 with an angular frequency Y _p = (9.5 ÷ 14.8) [units / rad]. The technical result of the invention is provided by saturating the blade rim with the number of blades and, respectively, the grooves 16 on the disk for fixing the blades located with an angular frequency taken from the range found in the invention. With a decrease in the number of blades and, respectively, grooves 16 on the rim of the disk 4 below the lower limit of the specified range Y _p <9.5 [u / rad], the lag of the flow from the rotation of the blade rim increases and the risk of loss of the HLD in the indicated compressor stage increases. Exceeding the upper limit of the specified range Y _p > 14.8 [units / rad] and a corresponding increase in the number of blades in the blade rim formed on the fourth stage disk 4 leads to an unjustified deterioration in efficiency and the risk of premature locking of the working fluid flow with the blade rim.

The blade 12 of the disks 1 and 3 is equipped with a conical ring element 17 and 18, made with an angle of inclination of the generatrix to the axis of the disk. The implementation of the angle of inclination of the generatrix provides an optimal increase in the volumetric rigidity of connecting the web 12 disks with a conical diaphragm 19 and 20, respectively, the pins 5 and 6 of the front and rear bearings of the rotor shaft and the resource of the shaft under conditions of multiple bending-torsion loads during operation of the compressor, provides the necessary compactness of the assembly without increase the material consumption of the shaft.

Thus, by improving the structural and aerodynamic parameters of the disks of all stages, combined into a drum-disk design of the rotor shaft, they achieve an increase in efficiency and a widening of the range of gas-dynamic stability modes of the engine’s low pressure, as well as a twofold increase in service life by providing increased bending stiffness of the shaft and maximum permissible voltages in the elements of the disks without increasing the material consumption of the KND rotor.

Claims (12)

1. A method of manufacturing a rotor shaft of a low-pressure compressor (KND) of a turbojet engine (TRD), characterized in that the rotor shaft is made drum-disk, assembling a four-stage design in terms of the number of disks, and shaft production is performed in three stages: at the first stage, assembly units are made , including trunnions of the front and rear shaft bearings, discs and cylindrical spacers; at the second stage, the assembly units are assembled into three mounting sections, each of which is non-separable, while the first section is assembled from the engine entrance, sequentially connecting the axle of the front support of the rotor shaft, the disk of the first stage, the disk of the second stage and equipped with a cylindrical spacer, the second section includes a disk of the third stage, to which the trunnion of the rear support and the cylindrical spacer, equipped with a flange from the opposite end, are permanently attached, and the third sec tion is performed in the form of a disk of the fourth stage; at the third stage, these mounting sections are sequentially detachably connected through cylindrical spacers and complete the installation of the rotor shaft structure by releasably connecting the cylindrical spacer of the second section with the fourth-stage disk forming the third section; moreover, the disks of all steps of the rotor shaft of the low pressure rotor are made of stamped blanks in the form of a single element, including a rim turning into an annular web with a hub, which is made with a central hole, and the rim is inscribed in a conditional surface of a truncated cone, expanding in the direction of flow of the working fluid, with an intermediate radius in the average conditional plane of the blade web, equal to the design radius of the inner contour of the engine duct in the specified section, counting from the shaft axis to the outer surface of a, and the gradient G _4ob conical extension of the rim, which during the manufacture of the disc of the fourth stage in a range taking

where R _max and R _min - the maximum and minimum radii of the outer surface of the rim of the disk of the fourth stage, and In _about - the axial width of the rim of the disk of the fourth stage; the rim of each disk is provided with grooves designed for rotor blades, which are evenly distributed around the perimeter and are inclined to the axis of the shaft, and the number and frequency of the grooves are increased in the direction of flow of the working fluid from the disk to the disk from the first to the third section, including placing the longitudinal axis of the grooves in the rim of the disk of the fourth stage with an angular frequency of Y = (9.5 ÷ 14.8) [units / rad] and a slope to the axis of the rotor in the projection onto the conditional axial plane normal to the radius drawn through the center point of the groove axis at an angle α, that is taken in the range of α = (24 ÷ 30) °. 2. A method of manufacturing a rotor shaft of a low-pressure compressor of a turbojet engine according to claim 1, characterized in that during the machining of the disk of the first stage from the front side of the sheet and the disk of the third stage from the back side of the sheet, they are turned up to the design dimensions, located under the rim of the indicated of disks a cantilever annular conical element for subsequent connection when assembling a section with conical diaphragms of trunnions of the front and rear shaft bearings, while the length of the generatrix of these conical elements ntov nevyhodyaschey operate beyond the outer flange corresponding to the disc, and compound tapered elements of said annular disks and diaphragms trunnions operate integrally; similarly, one-piece disks of the first and second steps are permanently connected by the rim shelves, they also attach the first intersection annular cylindrical spacer with a flange to the rear shelf of the second-stage disc, in which (36 ÷ 44) holes are made during the manufacturing process for subsequent releasable connection with the third-stage disc blade as a part the second section in the third final stage of manufacture of the rotor shaft. 3. The rotor shaft of a low-pressure compressor of a turbojet engine, characterized in that it is made of a drum-disk, four-stage in the number of disks and made by the method according to any one of paragraphs. 1,2. 4. The rotor shaft of a low-pressure compressor of a turbojet engine, comprising a housing with a flowing part, characterized in that it contains three mounting sections, two of which, the first and second, are non-separable, designed for serial connection with the formation of the rotor shaft equipped with working blades this first mounting section from the engine input includes a pin connected to the front support of the rotor shaft, a disk of the first stage, a disk of the second stage and a cylindrical spacer equipped with with a lance, the second section includes a third-stage disk connected to the axle of the rear support of the rotor shaft and a cylindrical spacer provided with a flange, and the third mounting section consists of a fourth-stage disk, each disk of all stages of each of the mounting sections being made as a single element including a rim, passing into an annular web reinforced with a hub provided with a central hole, the rim of each disk being provided with grooves that are evenly distributed along the perimeter and made inclined to the axis of the shaft, the axial axis of each of the grooves of the fourth-stage disk as part of the third mounting section forms, with the rotor axis, projected onto a conditional axial plane normal to the radius drawn through the center point of the groove axis, an angle α defined in the range of values α = (24 ÷ 30) ° and the grooves are evenly spaced around the perimeter of the disk with an angular frequency Y = (9.5 ÷ 14.8) [units / rad], while the fourth-stage disk rim in the third mounting section is made with increasing radius from the entrance to the exit from the section with radial expansion gradient G _4ob defined in Range

where R _max and R _min - the maximum and minimum radii of the outer surface of the rim of the disk of the fourth stage, and In _about - the axial width of the rim of the disk of the fourth stage. 5. The rotor shaft of the low-pressure compressor according to claim 4, characterized in that, as part of the third mounting section, the fourth-stage disk rim is symmetrically connected to the disk web to form equal-shouldered annular shelves, and the disk web is removably connected to the disk shelf of the previous stage through a cylindrical spacer forming a cantilever annular shell, the radius of the disk from the axis of the rotor shaft to the outer surface of the rim in the middle plane of the blade web is (0.53 ÷ 0.79) from the radius of the peripheral flow circuit of the engine. 6. The rotor shaft of the low-pressure compressor according to claim 4, characterized in that the cross-sectional configuration of the grooves of the rim of each of the disk sections of the specified set is made according to the dovetail type, while the fourth-stage disk as part of the third mounting section is made with a radial distance from the lower point of the hub to the outer surface of the rim of the disk, not less than 1.05 times greater than the radial distance in the light between the inner and peripheral contours of the lumen of the engine duct, in addition, sections of the outer surface between the grooves of the rims of the disks of all sections are made forming the inner surface of the flowing part of the engine, in the area of the disks of the indicated sections of the rotor shaft of the KND, and the front shelves of the rims of the disks of the third and fourth stages in the second and third mounting sections are each equipped with an annular groove for fixing the shanks of the rotor blades split ring elements. 7. A method of manufacturing a rotor shaft of a low-pressure compressor of a turbojet engine, characterized in that the rotor shaft is drum-disk, assembling a four-stage design in terms of the number of disks, and the shaft is manufactured in three stages; at the first stage, assembly units are made, including trunnions of the front and rear shaft bearings, discs and ring spacers, which are cylindrical; at the second stage, the assembly units are assembled into three mounting sections, each of which is non-separable, while the first section is assembled from the engine entrance, connecting the axle of the front support of the rotor shaft, the disk of the first stage, the disk of the second stage and equipped with a flange cylindrical spacer, the second section includes a disk of the third stage, to which the conical diaphragm of the axle of the rear support and the cylindrical spacer provided from the opposite end flange, and the third section operates as a disc of the fourth stage; at the third stage, the mounting sections are sequentially detachably connected through cylindrical spacers and complete the installation of the rotor shaft structure, releasably connecting the output spacer of the second mounting section with a fourth-stage disk forming the third shaft section; moreover, the disks of all steps of the rotor shaft of the low pressure rotor are made of stamped blanks in the form of a single element, including a rim turning into an annular web with a hub, which is made with a central hole, and the rim is inscribed in a conditional surface of a truncated cone, expanding in the direction of flow of the working fluid, with an intermediate radius in the average conditional plane of the blade web, equal to the design radius of the inner contour of the engine duct in the specified section, counting from the shaft axis to the outer surface of and, while the rim of each disk is provided with grooves that are evenly distributed around the perimeter and are inclined to the axis of the shaft, the number and frequency of the grooves being increased in the direction of flow of the working fluid from the disk to the disk and from the first section to the third, including placing longitudinal the groove axis in the rim of the fourth-stage disc with an angular frequency Y = (9.5 ÷ 14.8) [units / rad] and tilt to the rotor axis in the projection onto the conditional axial plane normal to the radius drawn through the center point of the groove axis at an angle α, which is taken in the range a range of values α = (24 ÷ 30) °, in addition, in the process of manufacturing the fourth-stage disk for the third mounting section, the rim is made with an external surface inscribed in a conditional truncated conical surface, with a slope of the surface forming in the axial plane of the rotor shaft at an angle φ = (1 ÷ 5) ° to the axis of the latter. 8. A method of manufacturing a rotor shaft of a low-pressure compressor of a turbojet engine according to claim 7, characterized in that in the manufacture of a fourth-stage disk of the third mounting section of the shaft, the disk rim is made with an inscribed outer surface in a conditional surface of a truncated cone radially increasing in the direction of flow of the working fluid with a gradient conical expansion of the rim G4 _r , which take in the range

where R _max and R _min - the maximum and minimum radii of the outer surface of the rim of the disk of the fourth stage, and In _about - the axial width of the rim of the fourth stage of the disk as part of the third mounting section. 9. The rotor shaft of a low-pressure compressor of a turbojet engine, characterized in that it is made of a drum-disk, four-stage in the number of disks and is made according to any one of paragraphs. 7.8. 10. The rotor shaft of a low-pressure compressor of a turbojet engine, comprising a housing with a flowing part, characterized in that it contains three sections intended for series connection with the formation of the rotor shaft supplied with blades, two of which, the first and second, are non-separable, while the first from the engine entrance, the section includes a pin connected to the front support of the rotor shaft, a first-stage disk, a second-stage disk and a cylindrical spacer equipped with a flange, the second section includes t the disk of the third stage, in communication with a cylindrical spacer provided with a flange, and the third is made up of a disk of the fourth stage; moreover, each disk is made in the form of a single element, including a rim turning into an annular web reinforced with a hub provided with a central hole, and the rim of each of the said disks is provided from the side facing the flow part with a system of grooves for the lock located at an angle to the axis of the rotor shaft connection with the rotor blades, in addition, the generatrix of the outer surface of the rim of the fourth-stage disk as part of the third mounting section makes an angle φ = (1 ÷ 5) ° with the axis of the rotor shaft in the axial plane of the latter. 11. The rotor shaft of the low-pressure compressor according to claim 10, characterized in that the longitudinal axis of each of the grooves of the fourth-stage disk as part of the third mounting section forms with the rotor axis projected onto a conditional axial plane normal to the radius drawn through the center point of the groove axis , the angle α, defined in the range of values α = (24 ÷ 30) °, and the grooves are evenly spaced around the perimeter of the disk with an angular frequency Y = (9.5 ÷ 14.8) [units / rad], while the rim of the fourth-stage disk as part of the specified mounting section is made with increasing from entrance to exit y section of radius gradient G _4ob radial expansion determined in the range

where R _max and R _min - the maximum and minimum radii of the outer surface of the rim of the disk of the fourth stage, and In _about - the axial width of the rim of the disk of the fourth stage as part of the third mounting section. 12. The rotor shaft of the low-pressure compressor according to claim 10, characterized in that the cross-sectional configuration of the grooves of the rim of each of the section disks is made according to the dovetail type, while the fourth-stage disk as part of the third mounting section is made with a radial distance from the lower point hubs to the outer surface of the rim of the disk, not less than 1.05 times greater than the radial distance in the light between the inner and peripheral contours of the lumen of the engine duct, in addition, sections of the outer surface between the grooves of the rims the disks of all sections are made forming the inner surface of the flowing part of the engine, in the area of the disks of the indicated sections of the rotor shaft of the low pressure rotor.

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