RU2630919C1 - Rotor forth stage impeller of high-pressure compressor (hpc) of turbojet engine (versions), hpc rotor impeller disc, hpc rotor impeller blade, hpc rotor impeller blade ring - Google Patents

Abstract

FIELD: engine devices and pumps.

SUBSTANCE: rotor shaft fourth stage impeller of THE HPC contains a disc and rotor blades, forming a blade ring. The disc includes a hub with a central bore, body and rim. Each blade consists of a shank, airfoil with a profile, formed by concave pressure side and convex back, and a root shroud on both sides of the feather, forming a bushing surface of the flow part together with the disc rim. And the chord line of the airfoil side edges in the blade root zone forms the airfoil incidence angle of α_K, increasing along the radial height of the airfoil with an airfoil twist rate of G_a.t=(148.2÷214.4) [deg/m], with the rotor axis in plane view. The blade airfoil is designed to axially and variably twist about the rotor axis. The twisting increases radially receding from the rotor axis. The exterior surface of the disc rim has a radius, which increases in the axial section of HPC towards the working medium flow. Radius R_d of the disc from the HPC rotor axis to the rim upper surface in the mean radial plane of the body is (0.67÷0.93) of radius R_p.c. of the peripheral contour of the flow part. The impeller is designed with the ratio of disc R_d and the mean height H_mh of the blade airfoil profile, which is R_d/H_mh=(5.1÷7.4). The disc rim is equipped with ring shrouds to provide the connection with the mating shrouds of the adjacent discs - a one-piece connection with the fifth stage disc and detachable connection with the third stage disc - shaping an integral ring area of the interior contour of the HPC flow part. The disc body is equipped with a ring tapered element, facing the third stage disc, integrating the fourth stage disc into the rotor shaft both through the rims of the previous disc of the rotor shaft drum-disc shell and a conical diaphragm and body of the third stage disc.

EFFECT: higher efficiency and gain in stall margin in all operation modes of the compressor when the life of the HPC rotor fourth stage impeller increases keeping the material consumption the same.

24 cl, 9 dwg

Description

The group of inventions relates to the field of aircraft engine manufacturing, namely to high-pressure compressors (HPC) of aircraft turbojet engines (turbojet engines).

Known impeller of a multi-stage compressor having a disk with blades mounted on it, including a feather and a shank. (Yu.S. Eliseev et al. Theory and Design of Gas Turbine and Combined Installations. 2nd ed. Moscow. Publishing House of MGTU named after NE Bauman. 2000. p. 621-624).

Known impeller of a multi-stage compressor having a disk with blades mounted on it, including a feather and a shank. The shank of the blade and the groove in the rim of the disk has a trapezoidal profile. The feather is connected to the shank through an intermediate element - the leg. Between the leg and the feather, a shelf is made with the formation of the flow part (A.A. Inozemtsev et al. Fundamentals of designing aircraft engines and power plants. Volume 2. M: Engineering 2008, pp. 39-42).

A compressor impeller is known having a disk with rotor blades installed in a groove, including a feather and a shank. The groove of the disk is made with broadening in depth in the cross section of the groove. (US 2013/0171343, 07/04/2013, Fig. 1, 2). Similar solutions are known from US 2005/0025622 A1, FIG. 1, US 2009/0246029 A1, FIG. 5, US 2005/0129522 A1, FIG. 1, US 1606029, FIG. 3, 4.

The disadvantages of the known solutions include the inadequacy of the system for selecting the set of necessary parameters for the general configuration of the impeller disk, affecting the formation of the configuration and the area of the bore of the flow part and the placement of blades in the groove of the rim of the disk of the disk, forming the aerodynamic processes of the interaction of the impeller of the fourth stage of the compressor rotor with the flow of the working fluid due to the lack of specification of the ranges of geometric and aerodynamic parameters of the spatial configuration the disk and the angular installation of the blades in the impeller of the fourth stage of the rotor, which makes it difficult to obtain the optimal combination of increased values of efficiency, reserves of gas-dynamic stability (GDU) of the compressor, as well as ensuring optimal dynamic strength and increased resource with a minimum of material consumption.

The problem solved by the group of inventions, united by a single creative concept, is to develop the impeller of the fourth stage of the rotor of the high-pressure compressor of the turbojet engine with improved structural and aerodynamic parameters of the spatial configuration of the disk and blades, providing the possibility of optimizing the profile and area of the passage sections of the engine ducts, sufficient to increase the flow rate of the compressible working fluid - air, the efficiency in the fourth stage of the HPC, the air flow in the subsequent stages K VD with an increased supply of GDU in all operating modes and engine life without increasing material consumption.

The problem is solved in that the impeller blade of the fourth stage as part of the rotor of a multi-stage high-pressure compressor HPC turbofan engine having a body with a flow part, a low-pressure turbine (HPH) with a shaft, a high-pressure turbine (HPH) and an HPC rotor including a shaft a drum-disk construction with disks and blade crowns, while the impeller rim of the impeller is provided with a groove for installing the blades, according to the invention, the blade contains a feather with a convex-concave profile formed in a curved trough and a convex back, conjugated inlet and outlet edges, as well as a shank and root shelf made integrally with a feather, a shank and a root shelf with a conical surface on both sides of the pen, forming a fragment of the sleeve surface of the duct part of the engine of the fourth stage of the HPC, and the shank of the blade is made with the possibility installation in the groove of the disk rim and has the configuration of the side and supporting surfaces, congruent to the profile of the mating surfaces of the groove with the formation of the castle connection type "annular groove" and provide iem angle α Profile Fitting pen to the rotor axis in projection on an axial schematic of the rotor plane normal to having a root section of the blade airfoil axis of the pen _to a value α = (29,4 ÷ 42,2) °, a cross section in the circumferential pen value α _n = (36.8 ÷ 52.9) °, while the blade feather is made with an axial twist variable with respect to the rotor axis, increasing with radial distance from the rotor axis with a pen twist gradient G _z defined in the projection onto the conditional axial plane in range

G _s.p. = (α _p -α _k ) / N _sr = (148.2 ÷ 214.4) [deg / m],

where α _to - the angle of installation of the profile of the feather blades in the root section; α _p - the same in the peripheral section; N _cf - the average height of the feather blades; in addition, the feather of the blade is made variable in width and height of the feather with a thickness defined in cross section as the difference in height of the back and trough relative to the chord connecting the input and output edges of the feather of the blade, while the maximum thickness of the profile of the feather of the blade is made the largest in the root section and decreases along the height of the peripheral end of the pen with a gradient G _{of standard fuel} equal to

G _ut = (C _to -C _p ) / N _cf = (2.5 ÷ 3.6) ⋅10 ^-2 [m / m],

where C _to - the maximum thickness of the profile of the feather of the scapula in the root section; With _p - the same in the peripheral section; N _cf - the average height of the feather blades.

In this case, the blade root may have a sole with a longitudinal axis located in a conventional plane normal to the rotor axis and may contain depth broadening made in cross section by two reciprocal mirror-symmetric dihedral protrusions, the upper faces of each of which are inclined to the conventional plane of the root of the shank at an angle β ₁ = (29 ÷ 40) °, and the lower faces are counter-inclined and form, each, with a conditional plane of the base of the shank angle β ₂ = (48 ÷ 69) °.

The shank can be made with a ratio of the average height H _{cf of the} blade feather profile to the average height of the shank h _cp , comprising H _cp / h _cp = (4.5 ÷ 6.1).

The feather of the blade can be made with a convex-concave profile formed by a concave trough of the profile, facing concavity in the direction of rotation of the rotor counterclockwise (view in np - direction of flight), and a convex back of the pen, convex in the direction of rotation of the rotor and in the direction of rotation clockwise.

Alternatively, the feather of the blade can be made with a convex-concave profile formed by a concave trough facing concavity in the direction of rotation of the rotor clockwise (view in np), and a convex back of the pen, convex in the direction of rotation of the rotor and against the direction of rotation clockwise (view by n.p.).

The problem in terms of the blade rim is solved by the fact that the blade rim of the impeller of the fourth stage as part of the rotor of a multi-stage high-pressure compressor turbofan engine, having a housing with a flowing part, a high-pressure pump with a shaft, a high pressure fuel pump and a rotor of the HPC, including a drum-disk design shaft with impeller disks , the rim of which is endowed with a groove for installing the working blades, according to the invention, contains blades uniformly spaced around the perimeter of the disk with an angular frequency of Y _l = (12.73 ÷ 17.52) [units / rad], with each blade of the scapular veins The fourth stage of the HPC rotor is made with the configuration and parameters described above, in addition, the ends of the root flange of each blade are made with the possibility of tightly adjoining the counter ends of the adjacent blades of the impeller rim facing them, forming a sleeve surface of the flow part, for which each flange the blades are made oblique with the repetition of the curvature of the inner surface of the engine duct in the area of the fourth stage of the HPC with an increase in the radius in the direction of flow of the working fluid and the angle ϕ of inclination of developing external surface of the shelf to the axis of the rotor, identical to the forming external surface of the rim of the disk and component ϕ = (10 ÷ 16) °.

The problem in terms of the disk of the compressor rotor is solved by the fact that the disk of the fourth stage impeller as part of the rotor of a multi-stage high-pressure compressor turbofan engine with a housing with a flow part, a low-pressure turbine with a shaft, a high-pressure turbine and an HPC rotor, including a drum-type shaft with disks of impellers equipped with blades, including a shank, a root shelf and a feather, as well as having a front support, equipped with a trunnion with a socket facing the specified disk with a conical diaphragm, according to the invention In this case, the disk is made in the form of a single element including a rim, a hub with a central hole and a web, while the radius of the disk R _d from the axis of the rotor to the outer surface of the rim in the middle radial plane of the web is (0.67 ÷ 0.93) from the radius R _{p .h.} the peripheral contour of the flowing part in the specified plane, and the rim of the disk is provided with an annular groove along the contour to accommodate the shanks of the working blades in it and is divided by the groove into two asymmetric differently high annular arms with peripheral annular conical shelves with the formation of the blades of the flowing surface contour together with the upper surface of the root shelves of the blades parts of the engine within the axial width of the rim of the disk of the fourth stage of the HPC rotor, while the outer surface of the rim is made with an inclination angle forming it relative to the axis of the rotor shaft and a radius increasing in the direction of movement of the flow of the working fluid in the axial section of the HPC with a gradient of G _R. defined in the range

where R _max and R _min - the maximum and minimum radii of the generatrix of the upper surface of the disk rim In _rev - the axial width of the disk rim bounded by the interscapular channel; in addition, to ensure the possibility of transmitting torque from the theater, the disk is equipped with a conical ring element in the form of an axisymmetric shell, common or combined with the disk blade facing the third stage disk and the transitional ring fragment of the conical diaphragm of the axle of the front support with the possibility of one-piece power connection with the latter .

The radius R _ts.o.s. the central hole of the hub can be made sufficient for free passage of the shaft of the theater and optionally component (0.31 ÷ 0.49) from the radius R _{d of the} disk, counting the latter from the axis of the rotor to the outer surface of the rim in the middle radial plane of the web.

The groove of the disk can be equipped with at least one inlet for installing the shanks of the blades and the fixing elements in the groove to fix the position of the blades in the groove.

The angle of inclination of the generatrix of the conical annular element of the disk and the conical diaphragm can be made uniform, variably defined in the range (44 ÷ 65) °, and the length of the generatrix of the conical element is assumed not to extend beyond the radial dimension of the rim of the disk, while the annular fragment of the composite conical diaphragm is provided with a flange for detachable connection with the blade disk of the third stage, for which holes are made in the flange for fasteners such as tight bolts spaced around the perimeter of the flange with an angular frequency Y _crepe = (3.82 ÷ 5.25) [units / glad].

The groove of the disk rim can be made with double broadening in depth, located respectively in the upper and in the bottom part of the groove and separated by a narrowing formed by two mirror-symmetric mating ring protrusions made with rounded opposed end sections of the profile in the groove cross section located at a distance providing the possibility of supporting the establishment between the shank of the blade, while the lower broadening of the annular groove of the rim of the disk is made with the faces forming the castle config “ring groove” type uration with an angle of mutual inclination of the side faces of (91 ÷ 98) °, and congruent with respect to dominant points of the supporting surfaces to the mating surfaces of the shank of the blade, and the upper groove broadening is made corresponding to the configuration, width and axial height difference of the front and back the edges of the groove, the axial inclination of the main part of the area of the upper surface of the root shelf of the scapula extending into the flow part, which in turn is identical to the required slope of the internal contour of the flow part on disk arrangement sowing area of the fourth stage of the HPC.

The length of the perimeter of the annular groove in the rim of the disk can be made sufficient to accommodate the shanks of the blades with an angular frequency of Y _l , defined in the range of values of Y _l = (12.73 ÷ 17.52) [units / rad].

The disk rim can be made with the possibility of detachable connection of the front shelf with the mating rear shelf of the third-stage disk rim, moreover, in the junction zone, the sections of the shelves of these disks are overlapable and fastened along the contour of the power drum-disk shell with fixing elements such as pins.

The task in terms of the impeller according to the first embodiment is solved by the fact that the impeller of the fourth stage as part of the rotor of a multi-stage high-pressure compressor turbofan engine with a housing with a flow part, a low-pressure turbine with a shaft, a high-pressure turbine and an HPC rotor, including a drum-type shaft design , as well as having a front support, equipped with a trunnion with a bell facing the specified impeller with a conical diaphragm, according to the invention, contains a blade ring and a disk endowed with an annular groove for mounting wreaths of the crown blades, and the disk is made in the form of a single element, including a hub with a central hole, a web and a rim, and the crown blades contain, each, a shank, a feather made with a profile formed by a concave trough and a convex back, and a root shelf with a conical surface along both sides of the pen, the radius R _d of the drive rotor axis ARCs to conventional conical surface coaxial with the rotor shaft and which describes an upper surface of the rim in the central radial plane of the web (0,67 ÷ 0,93) of the radius R _p.ch. the peripheral contour of the flowing part in the indicated plane, and the radius R _{c.oc of the} central hole of the hub is made sufficient for free passage of the shaft of the theater and optionally component (0.31 ÷ 0.49) from the radius R _{d of the} disk in the middle radial plane of the disk web; the rim of the disk is divided by an annular groove into two asymmetric, unevenly different annular shoulders, the peripheral sections of the annular shelves of which together with the outer surface of the root flanges of the blades form the sleeve surface of the contour of the engine ducts within the axial length of the rim of the disk of the fourth stage of the HPC rotor, and the outer surface of the rim is made with the angle of inclination of the generatrix relative to the axis of the rotor shaft and the radius increasing in the direction of movement of the flow of the working fluid in the axial section of the HPC with a gradient of G _R. defined in the range

where R _max and R _min - the maximum and minimum radii of the generatrix of the upper surface of the rim of the disk; In _about - the axial width of the rim of the disk, limited by the interscapular channel; in addition, the disk is equipped with an annular conical element in the form of an axisymmetric shell, common or combined with the disk blade, facing the third-stage disk and the transitional annular fragment of the conical diaphragm of the axle of the front support, while the disk rim is made with the possibility of transmitting torque from the TVD shaft detachable connection of the front shelf with the mating flange of the disk of the impeller of the third stage and one-piece connection of the rear shelf with the mating flange of the disk of the fifth stage impeller with the formation of the combined annular portion of the inner contour of the flow passage of the HPC and the double inclusion of the fourth-stage disk into the power shell of the drum-disk construction of the rotor shaft both directly through the rims of the previous disks of the drum-disk shell of the rotor shaft and through the conical diaphragm and the third disk steps.

The blades can be evenly spaced around the perimeter of the disk with an angular frequency of Y _l = (12.73 ÷ 17.52) [units / rad].

For radial-angular fixation of the position of the blades, an annular groove can be made with contact protrusions, the lower face of each of which is located at an angle to the reference plane in the bottom part of the groove, identical to the angle of inclination of the mating face of the shank of the blade to the sole of the shank, which is β ₁ = (29 ÷ 40) °, and from displacement in the circumferential direction in the annular groove of the blade, at least five fixing elements are fixed, which are made in the form of a prismatic insert with a configuration in cross section, congruent profile y ring groove, and are endowed, each, with a through threaded hole for the fixing screw.

The conical ring element of the disk can be made with the angle of inclination of the generatrix to the conditional middle plane of the web, identical in magnitude to the angle of inclination of the generatrices of the conical section from the rear shelf of the rim to the disk web and the transitional annular fragment of the conical diaphragm, which is equipped with a flange for power connection with the impeller disk of the third steps with the possibility of transmitting torque from the theater, while the angle of inclination of the generatrix of the conical annular element of the disk and the conical diaphragm is made, about limited in the range (44 ÷ 65) °, and the length of the generatrix of the conical element is assumed not to extend beyond the radial dimension of the disk rim.

The blade feather can be made with an axial twist variable with respect to the rotor axis, increasing with radial distance from the rotor axis with a pen twist gradient G _zp defined in the range of the projected axial plane

G _s.p. = (α _p -α _k ) / N _sr = (148.2 ÷ 214.4) [deg / m],

where α _to - the angle of installation of the profile of the feather blades in the root section; α _p - the same in the peripheral section; N _cf - the average height of the feather blades; in addition, the feather of the blade is made variable in width and height of the feather with a thickness defined in cross section as the difference in height of the back and trough relative to the chord connecting the input and output edges of the feather of the blade, while the maximum thickness of the profile of the feather of the blade is made the largest in the root section and decreases along pen height to the peripheral end.

The annular shelves of the disk rim can be made protruding beyond the size of the pen of the working blade to a width sufficient for interaction along the working fluid with the blades of the stator guide apparatus, while in the junction zone, sections of the mating flanges of the third and fourth stage discs are overlapable and stapled power drum-disk shell fixing elements such as pins.

The task in terms of the impeller according to the second embodiment is solved by the fact that the impeller of the fourth stage as part of the rotor of a multi-stage high-pressure compressor turbofan engine, having a housing with a flow part, a low-pressure turbine with a shaft, a high-pressure turbine and an HPC rotor, including a drum-disk design shaft , as well as having a front support, equipped with a trunnion with a bell facing the specified impeller with a conical diaphragm, according to the invention, contains a blade ring and a disk endowed with an annular groove for mounting wreaths of the crown blades, and the disk is made in the form of a single element, including a hub with a central hole, a web and a rim, and the crown blades contain, each, a shank, a feather made with a profile formed by a concave trough and a convex back, and a root shelf with a conical surface along both sides of the pen, and the shank of the blade is made with the possibility of installation in the groove of the rim of the disk and has a configuration of the side and supporting surfaces, congruent to the profile of the mating surfaces of the groove with the formation of a castle connection type "ring groove ”and ensuring the angle α of the installation of the profile of the pen to the axis of the rotor in the projection onto the conditional axial plane of the rotor normal to the axis of the feather of the blade with the value α _k = (29.4 ÷ 42.2) ° in the root section of the pen and in the peripheral section pen value α _p = (36.8 ÷ 52.9) °, in addition, the feather of the blade is made with an axial twist variable with respect to the rotor axis, increasing with radial distance from the rotor axis with the pen twist gradient G _z defined in the projection on conditional axial plane in the range

G _s.p. = (α _p -α _k ) / N _sr = (148.2 ÷ 214.4) [deg / m],

where α _to - the angle of installation of the profile of the feather blades in the root section; α _p - the same in the peripheral section; N _cf - the average height of the feather blades; and the blades are uniformly spaced around the perimeter of the disk with an angular frequency of Y _l = (12.73 ÷ 17.52) [units / rad], and the rim of the disk is divided by an annular groove into two asymmetric uneven annular shoulders, the peripheral sections of the annular shelves of which together with the outer the surface of the root shelves of the blades form a sleeve surface of the contour of the engine ducts within the axial length of the rim of the disk of the fourth stage of the HPC rotor with an angle ϕ of inclination of the outer surface to the axis of the rotor, identical to the outer surface of the root shelf of the blade; to ensure the transmission of torque from the TVD shaft, the disk rim is made with the possibility of detachable connection of the front shelf with the mating disk of the rim of the impeller of the third stage and one-piece connection of the rear shelf with the mating disk of the disk of the impeller of the fifth stage with the formation of the combined annular section of the inner contour of the flow part ; wherein the impeller is configured to R _d disk radius ratio from the rotor shaft axis ARCs to conventional conical surface, describing the top surface of the disk rim in the middle of the radial web plane of the disc, to the average height H _cf. profile of the blade, constituting R _d / N _cp = ( 5.1 ÷ 7.4).

In this case, the disk can be made with a radius R _d from the axis of the HPC rotor to the conditional conical surface, coaxial with the rotor shaft and describing the upper surface of the rim in the middle radial plane of the web, comprising (0.67 ÷ 0.93) from the radius R _{P. .} the peripheral contour of the flowing part in the indicated plane, and the radius R _{c.oc of the} central hole of the hub is made sufficient for free passage of the shaft of the theater and optionally constituting (0.31 ÷ 0.49) from the radius R _{d of the} disk in the middle radial plane of the disk web.

The disk can be equipped with an annular conical element in the form of an axisymmetric shell, common or combined with the disk blade facing the third-stage disk and the transitional ring fragment of the conical diaphragm of the axle of the front support with the possibility of one-piece power connection with the latter and ensuring the transmission of torque from the TVD shaft with duplicated the inclusion of the fourth-stage disk in the power shell of the drum-disk design of the rotor shaft as directly through the rims of the previous drum discs but-disc rotor shaft casing, and through tapered aperture and the web drive the third stage.

For radial-angular fixation of the position of the blades, an annular groove can be made with contact protrusions, the lower face of each of which is located at an angle to the reference plane in the bottom part of the groove, identical to the angle of inclination of the mating face of the shank of the blade to the sole of the shank, which is β ₁ = (29 ÷ 40) °, and from displacement in the circumferential direction in the annular groove of the blade, at least five fixing elements are fixed, which are made in the form of a prismatic insert with a configuration in cross section, congruent profile y ring groove, and are endowed, each, with a through threaded hole for the fixing screw.

The annular shelves of the disk rim can be made protruding beyond the size of the pen of the working blade to a width sufficient for interaction along the working fluid with the blades of the stator guide apparatus, while in the junction zone, sections of the mating flanges of the third and fourth stage discs are overlapable and stapled power drum-disk shell fixing elements such as pins.

The technical result of the invention, achieved by the above set of essential features of the impeller of the fourth stage of the HPC rotor of the turbojet engine, including the disk and rotor blades, together making up the blade rim of the impeller, consists in increasing the efficiency and expanding the range of gas-dynamic stability of the compressor by 2.5% with increasing resource impeller 2 times.

The invention is illustrated by drawings, where:

in FIG. 1 shows the impeller of the fourth stage of the rotor KVD TRD, a longitudinal section;

in FIG. 2 - a fragment of the rim of the disk of the impeller with blades, side view;

in FIG. 3 - fragment of the blade rim of the impeller, top view;

in FIG. 4 - impeller blade, top view;

in FIG. 5 - feather blades of the impeller, a cross section;

in FIG. 6 - shank of the blade of the impeller, front view;

in FIG. 7 - the rim of the disk of the impeller, a longitudinal section;

in FIG. 8 - a fragment of the rim of the disk with the inlet for installation in the groove of the shanks of the blades, a longitudinal section;

in FIG. 9 - a fragment of the rim of the disk with a locking element for fixing the position of the blades in the groove, a longitudinal section.

A multi-stage high-pressure compressor of a turbojet engine includes a housing with a flowing part, a low-pressure turbine with a shaft, a high-pressure turbine and an HPC rotor, including a drum-disk design shaft with a front support and with a tubular part of the rotor shaft on the other side. The front support of the rotor shaft is provided with a trunnion with a flared facing to the specified impeller conical diaphragm.

In the group of inventions, united by a single creative concept, the impeller of the fourth stage of the compressor rotor (Fig. 1) contains a disk 1, endowed with a groove 2 for installing the rotor blades 3, which together comprise the blade rim of the impeller.

The blades of the blade rim contain, each, made in one piece shank 4, feather 5 and the root shelf 6 with a conical surface on both sides of the feather 5. The disk 1 of the impeller is made in the form of a single element, including a hub 7 with a Central hole 8, the blade 9 and the rim 10, endowed with a groove 2 for installing the shanks of 4 blades. The blades 3 are evenly spaced around the perimeter of the disk 1 with an angular frequency of Y _l = (12.73 ÷ 17.52) [units / rad]. The blade feather 5 is made with a convex-concave profile formed by a concave trough 11 and a convex back 12, conjugated by the input and output edges 13 and 14.

The shank 4 of the blade is made for installation in the groove 2 of the rim 10 of the disk 1, the Shank 4 is made with the configuration of the side and supporting surfaces, congruent to the profile of the mating surfaces of the groove 2 with the formation of the castle connection type "annular groove" and providing the angle α of the installation profile of the pen 5 to the axis 15 of the rotor in the projection onto the conditional axial plane of the rotor normal to the axis of the feather of the blade with α _k = (29.4 ÷ 42.2) ° in the root section of the pen, and α _p = (36.8 ÷ 52 in the peripheral section of the pen , 9) °.

The blade feather 5 (Fig. 4) is made with an axial twist variable relative to the rotor axis 15, increasing with a radial distance from the rotor axis with a feather twist gradient G _z defined in projection onto a conditional axial plane in the range

G _s.p. = (α _p -α _k ) / N _sr = (148.2 ÷ 214.4) [deg / m],

where α _to - the angle of installation of the profile of the feather blades in the root section; α _p - the same in the peripheral section; N _cf - the average height of the feather blades.

The blade feather 5 (FIG. 5) is made variable in width and height of the feather thickness, defined in cross section as the difference between the heights of the back 12 and the trough 11 relative to the chord 16 connecting the input and output edges 13 and 14 of the blade feather. The maximum thickness of the blade profile of the pen 5 is made greatest at the root section and decreasing in height to the peripheral end of the pen 17 with a gradient G _{of fuel equivalent} equal to

G _ut = (C _to -C _p ) / N _cf = (2.5 ÷ 3.6) ⋅10 ^-2 [m / m],

where C _to - the maximum thickness of the profile of the feather of the scapula in the root section; With _p - the same in the peripheral section; N _cf - the average height of the feather blades.

The shank 4 of the blade (Fig. 6) has a sole 18 with a longitudinal axis located in a conventional plane normal to the axis 15 of the rotor. The shank 4 contains a broadening in depth, made in cross section by two reciprocal mirror-symmetric dihedral protrusions. The upper faces 19 of each protrusion are inclined to the conditional plane of the sole of the shank 18 at an angle β ₁ = (29 ÷ 40) °. The lower faces 20 are made obliquely inclined and each form, with a conditional plane of the sole 18 of the shank, an angle β ₂ = (48 ÷ 69) °.

The ends 21 of the root shelf 6 of each blade (Fig. 3) are made with the possibility of tight adjacency to facing the response ends of the shelf of adjacent blades of the rim of the impeller, forming a sleeve surface of the flow part. For this, the root shelf 6 of the blade 3 is made inclined with a repetition of the curvature of the inner surface of the engine duct in the fourth stage of the HPC with an increase in the radius in the direction of flow of the working fluid and an angle ϕ of inclination of the outer surface of the shelf 6 to the axis of the rotor, identical to the generatrix of the outer surface of the rim 10 of the disk and components ϕ = (10 ÷ 16) °.

The blade 3 is made with a ratio of the average height H _{cp of the} profile of the feather 5 of the scapula to the average height h _{cp of the} shank 4, which is H _cp / h _cp = (4.5 ÷ 6.1).

The feather 5 of the blade is made with a convex-concave profile formed by a concave trough 11 of the profile, facing concavity in the direction of rotation of the rotor counterclockwise (view in np - direction of flight), and a convex back of the pen 12, convex in the direction of rotation of the rotor and clockwise.

Variant feather blade is made with a convex-concave profile formed by a concave trough facing concavity in the direction of rotation of the rotor clockwise (np view), and a convex back of the pen convex in side against rotation of the rotor and counterclockwise rotation (view by n.p.).

Disk 1 of the impeller of the fourth stage is made with a radius R _d from the axis 15 of the HPC rotor to a conditional conical surface coaxial with the rotor shaft and describing the upper surface of the rim 10 in the middle radial plane of the blade 9, which is (0.67 ÷ 0.93) from the radius R _pp the peripheral contour of the flowing part in the specified plane. Radius R _co.c. the central hole of the hub is made sufficient for free passage of the shaft of the theater and optionally component (0.31 ÷ 0.49) from the radius R _{d of the} disk from the axis 15 of the HPC rotor to the upper surface of the rim 10 in the middle radial plane of the disk 9.

To accommodate the shanks of the blades 3, the rim 10 of the disk 1 is provided with an annular groove 2 along the contour. The rim 10 is divided by a groove 2 into two asymmetric uneven annular arms 22, 23 with peripheral annular conical shelves 24 and 25, respectively, with the formation of 6 blades 3 together with the upper surface of the root shelves the sleeve surface of the flow path of the engine within the axial width of the rim of the disk of the fourth stage of the HPC rotor.

The outer surface of the rim 10 is made with an angle of inclination of the generatrix 26 relative to the axis 15 of the rotor and a radius increasing in the direction of flow of the working fluid in the axial section of the HPC with a gradient of G _{R rev.} defined in the range

where R _max and R _min - the maximum and minimum radii of the generatrix of the upper surface of the rim of the disk In _about - the axial width of the rim of the disk, limited by the interscapular channel.

In this case, the impeller is made with a ratio of the radius R _{d of the} disk 1 from the axis 15 of the HPC rotor to the conditional conical surface describing the upper surface of the rim 10 of the disk in the middle radial plane of the blade web 9 of the disk to the average height H _{cf of the} blade profile 5 of the blade, which is R _d / N _avg = (3.1 ÷ 4.6).

The groove 2 of the rim 10 of the disk (Fig. 7) is made with double broadening in depth, located respectively in the upper and in the bottom parts 27 and 28 of the groove and separated by a narrowing, which is formed by two mirror-symmetric mating ring protrusions 29. The protrusions 29 are made with rounded opposed end faces sections of the profile in the cross section of the groove located at a distance providing the possibility of supporting the establishment between them of the shank 4 of the scapula. The broadening in the bottom bottom part 28 of the groove 2 of the rim of the disk is made with faces 30 with the formation of the castle configuration of the type of "annular groove" with an angle of mutual inclination of the side faces 30 of (91 ÷ 98) °, and congruent with respect to the dominant points of the supporting surfaces to the response faces 19 and 20 shanks 4 shovels. The broadening in the upper part 27 of the groove 2 is made corresponding to the configuration, width and axial height difference of the front and rear edges of the groove 2, to the axial inclination of the main part of the upper surface area of the root shelf 6 of the blade, which extends into the flow part, which in turn is identical to the required inclination of the inner the contour of the flowing part on the axial portion of the disk arrangement of the fourth stage of the HPC.

The groove 2 of the rim 10 of the disk 1 is equipped with at least one inlet 31 for installation in the groove of the shanks 4 of the blades (Fig. 8) and the fixing elements 32 for fixing the position of the blades in the groove. For radial-angular fixation of the position of the blades 3 in the rim 10 of the disk, the annular groove 2 is made with contact protrusions 29 with the possibility of holding the blades from moving in the radial direction from the action of centrifugal forces. The lower edge of the protrusion 29 is located at an angle to the conventional plane of the bottom of the groove, identical to the angle β _{1 of the} inclination of the counter face 20 of the shank 4 of the blade to its sole 18. From the displacement in the circumferential direction (Fig. 9) in the annular groove 2 of the blade is fixed by at least five the locking elements 32. The locking elements 32 are made in the form of a prismatic insert with a configuration in cross section, congruent to the profile of the annular groove 2, and each endowed with a through threaded hole for the fixing screw 33.

To ensure the transmission of torque from the shaft of the theater, the rim 10 of the disk 1 is made with the possibility of detachable connection of the front shelf 24 with the mating flange of the rim of the disk of the impeller of the third stage and the integral connection of the rear flange 25 of the rim with the mating flange of the disk of the impeller of the fifth stage with the formation of a combined annular plot of the internal contour of the flow part of the HPC. The annular shelves 24 and 25 of the rim 10 of the disk are made protruding beyond the size of the pen 5 of the working blades 3 to a width sufficient to interact along the working fluid with the blades of the stator guide vane. In the junction zone, sections of the mating flanges of the third and fourth stage discs are lapped and fastened along the contour of the power drum-disk shell with fixing elements such as pins, for which holes 34 for the fixing elements are made in the flange 24 of the rim.

In addition, the disk 1 is equipped with a conical ring element 35, which is made in the form of an axisymmetric shell, common or combined with the blade web 9. The annular element 35 is made facing the third stage disk and the transitional annular fragment 36 of the composite conical diaphragm of the axle of the front support with the possibility of one-piece power connection with the latter. The conical ring element 35 of the disk is made with an inclination angle of the generatrix to the conditional middle plane of the web 9, identical in magnitude to the angle of inclination of the generatrices of the conical section from the rear shelf 25 of the rim 10 to the web 9 of the disk and the transitional annular fragment 36 of the conical diaphragm. The angle of inclination of the generatrix of the conical annular element 35 of the disk and the conical diaphragm is made, variably defined in the range (44 ÷ 65) °. The length of the generatrix of the conical element 35 is assumed not to extend beyond the radial dimension of the rim 10 of the disk 1. In this case, the transitional annular fragment 36 of the diaphragm is provided with a flange 37 for detachable connection with the blade web of the third stage. For this, holes 38 are made in flange 37 for fasteners of the type of tightening bolts spaced around the perimeter of the flange with an angular frequency Y _crepe = (3.82 ÷ 5.25) [units / rad].

Thus, the detachable connection of the front shelf 24 of the rim 10 of the disk of the impeller of the fourth stage with the mating flange of the rim of the disk of the impeller of the third stage is made with the duplicated inclusion of the disk of the fourth stage in the transmission of torque, as directly through the rims of the previous disks of the drum-disk shell of the rotor shaft, and through the conical diaphragm and the blade disk of the third stage.

An example implementation of the invention.

The impeller of the fourth stage of the HPC engine consists of a disk 1 and rotor blades 3 mounted on it. Disk 1 is made by die-forging from a forging in the form of a single element, including a massive hub 7, web 9 and rim 10 made in one piece.

The manufactured disk has the following geometric parameters: overall hub width - 21 mm; diameter of the central hole of the hub - 198 mm; web thickness - 4 mm; the width of the rim bounded by the interscapular channel is 23 mm; minimum and maximum diameters of the outer surface of the rim of the disk - 498 mm and 508 mm, respectively; the angle ϕ of the inclination of the outer surface of the rim of the disk is 13 °.

The blade 3 of the impeller of the fourth stage of the rotor KVD TRD is stage-by-stage made from the bar of an aircraft alloy. At the first stage, a fragment of the rod of the required length is cut, from which the blade is prepared by electric upsetting, followed by machining, with local thickenings in the areas of the root shelf 6. In the next step, the workpiece is subjected to general heating in an electric furnace to the state of thermoplasticity and hot stamping is performed using a stamp, consisting of two reciprocal profiled half-matrices. The working surface of one of the die semi-matrices includes a section whose shape is made of the mating spatial surface of the back 12 of the pen 5 of the scapula. The working surface of the other half-matrix of the stamp includes a section whose shape is made of the mating spatial surface of the trough 11 of the pen 5 of the scapula. After that, the blade is subjected to machining, including grinding the flap milling, pulling the shank 4.

The refinement of the streamlined surfaces of the profiles of the pen 5 and the root shelf 6 is performed by milling with subsequent polishing. The contact ends 21 of the root shelves 6 are strengthened by applying a high-strength layer to them.

The blade made in this way consists of a single pen 5 with a shank 4 and a root shelf 6, made as a segment of the assembled ring of the blade ring of the impeller of the fourth stage of the turbine engine compressor rotor.

The profile of the pen 9 of the scapula has the following geometric parameters:

- in the root section, the profile of the feather blade is made with a maximum profile thickness With _max = 2.6 mm; the length of the chord 16 connecting the inlet and outlet edges 13 and 14 of the blade feather - 25 mm; the angle α _{to the} installation profile of the pen to the axis of the rotor is 36.1 °;

- in the peripheral section, the profile of the feather blade is made with a maximum thickness of the profile With _max = 0.94 mm; feather chord length adopted 36 mm; the angle α _p setting the profile of the pen is 45 °;

- the average height H _cf pen profile is 47 mm;

- the average height h _{cp of the} shank is 9 mm

The root shelf 6 of the blade is made with a circumferential width of 18 mm with contact ends 21 made parallel to the axis of the rotor and the angle ϕ of inclination of the generatrix of the outer surface of the shelf 6 to the axis 15 of the rotor ϕ = 13 °.

On the outside of the rim 10 is performed by pulling an annular groove 2 for mounting the blades. The groove is made with two inlet holes 31. The blades 3 are kept from moving in the radial direction from the action of centrifugal forces using contact tabs 29. The blades 3 are kept in the disk 1 from moving in the circumferential direction 2 with the help of the locking elements 32. The blades 3 are mated at the return ends 21 adjacent root shelves.

During the operation of the turbojet engine, the fourth stage impeller disk 1 is driven into rotation by transmitting torque from the turbine engine through the drum-disk design of the compressor rotor shaft with the inclusion of the blades 3 of the impeller. As a result, air flow is forced into the compressor. On the concave surface in the form of the trough 11 of the feather 5 of the blade 3, an increased pressure zone is created, and on the convex surface forming the back 12 of the feather 5, a reduced pressure zone is created, which enhances the formation of a directed air flow. Rotating blades 3 of the rotor impeller transmit energy to the air stream, directing the compressible stream to the stator vanes of the fourth stage, and after alignment in the last, the flow enters the subsequent stages of the compressor. At the same time, the fourth-stage disk 1 accepts centrifugal loads and, through the duplicated inclusion of the disk into the torque transmission, directly transfers the radial and axial loads to the rotor shaft bearings through the rims of the previous disks of the drum-disk shell of the rotor shaft, and through the conical diaphragm and the disk of the third-stage disk .

The technical result of the present invention is achieved by a combination of the design solutions and geometric parameters of the main elements of the impeller disk of the fourth stage of the compressor rotor, namely, the radial parameters of the disk, the geometric configuration of the rim 10, the combination of the tapering web 9 and the axial width of the hub 7, compensating for the weakening of the web 9 of the disk by the central hole 8, which leads to a decrease in the material consumption and an increase in the maximum allowable forces in the dis ka. The diameter of the hole 8 in the hub 7 is accepted sufficient for free passage of the shaft of the fuel assembly and repair and technological access to the connections of the compressor shaft. On the outer side of the disk rim 10, an annular groove 2 is fastened for fixing the blades, while providing the possibility of installing the shank and feather of the blade at an angle that creates the greatest pressure difference at the inlet and outlet of the working fluid flow from the impeller of the fourth stage of the compressor rotor and the most favorable conditions are created works that increase the supply of gas turbine, efficiency and resource with minimal material consumption of the disk. The exit of the values of the angle α outside the declared range will lead to a significant limitation of the GDU stock during multi-mode operation of the compressor, a decrease in the efficiency of the rotor stage and an increase in the risk of an accidentally dangerous stall of the air flow from the vanes of the fourth stage of the compressor rotor of the fourth rotor blade 3 of the compressor wheel with the resulting loss of the GDU . With an increase in the angle α, the voltage in the blades unreasonably increases at all compressor operating modes, which leads to a decrease in the resource of the disk-blade-wreath system, an increase in the material consumption of the blades installed on the disk, and, ultimately, to a heavier compressor and a decrease in engine operating efficiency. The technical result of the invention is provided by saturating the blade rim with the number of blades arranged with an angular frequency taken from the range found in the invention. When the number of blades decreases below the lower limit of the specified range Y _l <12.73 [units / rad], the lag of the flow from the rotation of the blade rim increases and the risk of loss of HLD in the indicated compressor stage increases. Exceeding the upper limit of the specified range Y _l > 17.52 [units / rad] and a corresponding increase in the number of blades in the scapular blade formed on the fourth-stage disk leads to an unjustified deterioration in efficiency and the risk of premature blocking of the working fluid flow with the scapular crown. In addition, the claimed geometry of the groove provides increased concentration under the action of operational loads and increases the resource of the impeller.

Similar processes take place to give a positive result and a negative subject when going beyond the gradients found in the group of inventions range limits G _zp = (148,2 ÷ 214,4) [deg / m] Height H _cf. pen 5 blades. When performing a three-dimensional profile of the feather of the blade with gradient values G _zp <148.2 [deg / m], the range of the GDU of the compressor is significantly limited, the efficiency of the stage decreases and the risk of an accidentally dangerous stall of the air flow from the convex back of 12 feather 5 of the blade with the resulting loss of GDU. An increase in the ratio of the difference in the angles of installation of the chord 16 of the pen 5 along the height of the scapula to the values of the gradient G _zp exceeding the upper limit leads to an unacceptable decrease in the opening angle of the peripheral section of the pen 9 of the scapula, which in turn leads to a decrease in efficiency and a negative decrease in the range of the compressor GDU and unacceptable mismatch of the fourth stage of the rotor with the previous and subsequent stages of the compressor.

The technical result increasing the impeller resource twice achieved under condition the thickness difference ratio to the average height of the blade 5, Feather received within found in invention _{reference fuel} specified gradient G value range = (2.5 ÷ 3.6) ⋅10 ^-2 [m / m] due to the provision of the required static and dynamic stiffness with optimal material consumption of the blade profile of the blade. When the gradient values G _{reference fuel} <2.5⋅10 ^-2 [m / m] an excessive increase in material consumption occurs due to the increase in the thickness of the peripheral part of the blade feather unjustified by real load combinations, which leads to an overestimation of the compressor mass and a decrease in engine efficiency. When the gradient values G _{reference fuel} > 3.6⋅10 ^-2 [m / m] the required increase in the resource of the blade is not achieved due to a decrease in dynamic strength during operation of the compressor due to an unjustified increase in the parameters of bending vibrations of the pen profile with an unacceptable decrease in the maximum thickness of the profile in the most loaded peripheral part of the length of the pen shoulder blades.

The technical result of the group of inventions is also achieved when implementing the invention with the claimed range of ratios (R _d / R _s.c. ) and (R _d / N _sr ), because a decrease in the values of these relations will lead to an unjustified decrease in the radius of the disk, an unaccounted increase in the radial height of the blades, which as a result will violate the inlet and outlet aerodynamic parameters of the design of the impeller and the flow of the working fluid — air, and will also worsen gas-dynamic stability during transient engine operation. An increase in the values of these relations will lead to an aerodynamically unacceptable decrease in the area of the flow passage of the engine in the zone of the fourth stage of the turbojet compressor, which will violate the required dynamic flow rate balance of the working fluid and will require redesigning the geometric parameters of the flow part of the subsequent stages of the HPC. In addition, a decrease in the gradient G _{R. о} <0.17 will lead to an unacceptable negatively small increase in the radius of the disk of the fourth stage and, accordingly, will not provide the required decrease in the flow section in the axial section of the width of the rim of the disk, which will not allow to obtain the necessary increase in pressure of the working fluid, which should be obtained in the fourth stage of the HPC turbojet engine to achieve a technical result in the implementation of the invention.

Thus, by improving the design and aerodynamic parameters of the impeller of the fourth stage, they increase the efficiency and expand the range of regimes of gas-dynamic stability of the engine compressor without increasing the material consumption.

Claims (36)

1. The impeller blade of the fourth stage as part of the rotor of a multi-stage high pressure compressor (HPC) of a turbojet engine (turbojet engine) having a body with a flow part, a low pressure turbine (HPH) with a shaft, a high pressure turbine (HPH) and an HPC rotor including a shaft a drum-disk construction with disks and blade crowns, while the impeller rim of the impeller is provided with a groove for installing the blades, characterized in that the blade contains a feather with a convex-concave profile formed by a concave trough and a convex sp the shank and the root shelf with a conical surface on both sides of the pen, forming a fragment of the sleeve surface of the flowing part of the engine of the fourth stage of the HPC, with the shank of the blade made with the possibility of installation in the groove of the rim the disk and has a configuration of the side and supporting surfaces, congruent to the profile of the mating surfaces of the groove with the formation of the castle connection type "annular groove" and providing the angle α of the installation profile pen to the rotor axis in the projection onto the conditional axial plane of the rotor normal to the pen axis of the blade with α _k = (29.4 ÷ 42.2) ° in the root section of the pen, and α _p = (36, 8 ÷ 52.9) °, while the feather of the blade is made with an axial twist variable with respect to the rotor axis, increasing with radial distance from the rotor axis with a pen twist gradient G _zp defined in the range of the projected axial plane G _s.p. = (α _p -α _k ) / N _sr = (148.2 ÷ 214.4) [deg / m], where α _to - the angle of installation of the profile of the feather blades in the root section; α _p - the same in the peripheral section; N _cf - the average height of the feather blades; in addition, the feather of the blade is made variable in width and height of the feather with a thickness defined in cross section as the difference in height of the back and trough relative to the chord connecting the input and output edges of the feather of the blade, while the maximum thickness of the profile of the feather of the blade is made the largest in the root section and decreasing in height pen to the peripheral end with a gradient G _{of standard fuel} equal to G _ut = (C _to -C _p ) / N _cf = (2.5 ÷ 3.6) ⋅10 ^-2 [m / m], where C _to - the maximum thickness of the profile of the feather of the scapula in the root section; With _p - the same in the peripheral section; N _cf - the average height of the feather blades. 2. The impeller blade of the fourth stage of the HPC rotor according to claim 1, characterized in that the shank of the blade has a sole with a longitudinal axis located in a conventional plane normal to the axis of the rotor and contains a broadening in depth, made in cross section by two mirror-symmetrical counterparts two-sided protrusions, the upper faces of each of which are inclined to the conditional plane of the base of the shank by an angle β ₁ = (29 ÷ 40) °, and the lower sides are counter-inclined and form, each, with the conditional plane of the sole of the shank, the angle β ₂ = ( 48 ÷ 69) °. 3. The blade of the impeller of the fourth stage of the HPC rotor according to claim 1, characterized in that the shank is made with a ratio of the average height H _{cf of the} blade feather profile to the average height h _{cp of the} shank comprising H _cf / h _cf = (4.5 ÷ 6, one). 4. The impeller blade of the fourth stage of the HPC rotor according to claim 1, characterized in that the blade feather is made with a convex-concave profile formed by a concave trough of the profile, facing concavity in the direction of rotation of the rotor counterclockwise (view in n / a - direction flight), and the convex back of the pen, convex to the side against the rotation of the rotor and in the direction of rotation of the clockwise. 5. The impeller blade of the fourth stage of the HPC rotor according to claim 1, characterized in that the feather of the blade is made with a convex-concave profile formed by a concave trough facing the concavity in the direction of rotation of the rotor clockwise (np view), and the convex back of the pen, convex to the side against the rotation of the rotor and against the direction of rotation of the clockwise direction (view in np). 6. The blade wheel of the impeller of the fourth stage as part of the rotor of a multi-stage high-pressure compressor turbofan engine, having a housing with a flow part, a high-pressure pump with a shaft, a high-pressure fuel pump and a rotor of the HPC, including a drum-disk design shaft with impeller disks, each of which has a groove for installation of working blades, characterized in that it contains blades uniformly spaced around the perimeter of the disk with an angular frequency of Y _l = (12.73 ÷ 17.52) [units / rad], with each blade of the blade crown of the fourth stage of the HPC rotor liu to Bom from 1-5, in addition, the ends of the root flange of each blade are made with the possibility of tightly adjoining the counter ends of the adjacent blade blades of the impeller rim facing them, forming a sleeve surface of the flowing part, for which the shelf of each blade is made inclined with the curvature of the inner surface of the flowing part engine in the zone of the fourth stage of the HPC with increasing radius in the direction of flow of the working fluid and the angle ϕ of inclination of the generatrix of the outer surface of the shelf to the axis of the rotor, identical to the generatrix of the outer surface spacing of the rim of the disk and components ϕ = (10 ÷ 16) °. 7. The impeller disk of the fourth stage as part of the rotor of a multi-stage high-pressure compressor turbofan engine, having a housing with a flowing part, a low-pressure turbine of the high-pressure turbine with a shaft, a high-pressure turbine and an HPC rotor, including a drum-disk design shaft with impeller disks equipped with blades, including a shank , a root shelf and a feather, as well as having a front support, equipped with a trunnion with a bell facing the specified disk with a conical diaphragm, characterized in that the disk is made in the form of a single element, including a rim, hubs y with a central hole and the web, while the radius of the disk R _d from the axis of the rotor to the outer surface of the rim in the middle radial plane of the web is (0.67 ÷ 0.93) from the radius R of the _PC the peripheral contour of the flowing part in the indicated plane, and the rim of the disk is provided with an annular groove along the contour to accommodate the shanks of the blades in it and is divided by the groove into two asymmetric uneven annular shoulders with peripheral annular conical shelves with the formation of the blades of the bushing surface of the flow path contour together with the upper surface of the root shelves parts of the engine within the axial width of the rim of the disk of the fourth stage of the HPC rotor, while the outer surface of the rim is made with an inclination angle forming it relative to the axis of the rotor shaft and a radius increasing in the direction of movement of the flow of the working fluid in the axial section of the HPC with a gradient of G _R. defined in the range

where R _max and R _min - the maximum and minimum radii of the generatrix of the upper surface of the disk rim In _rev - the axial width of the disk rim bounded by the interscapular channel; in addition, to ensure the possibility of transmitting torque from the theater, the disk is equipped with a conical ring element in the form of an axisymmetric shell, common or combined with the disk blade facing the third stage disk and the transitional ring fragment of the conical diaphragm of the axle of the front support with the possibility of one-piece power connection with the latter . 8. The impeller disk of the fourth stage of the HPC rotor according to Claim 7, characterized in that the radius R is _t.o.s. the central hole of the hub is sufficient for free passage of the shaft of the theater and optionally component (0.31 ÷ 0.49) from the radius R _{d of the} disk, counting the latter from the axis of the rotor to the outer surface of the rim in the middle radial plane of the web. 9. The impeller disk of the fourth stage of the HPC rotor according to claim 7, characterized in that the groove of the disk is provided with at least one inlet hole for installing the shanks of the blades and fixing elements in the groove to fix the position of the blades in the groove. 10. The impeller disk of the fourth stage of the HPC rotor according to claim 7, characterized in that the angle of inclination of the generatrix of the conical annular element of the disk and the conical diaphragm is made uniform, optionally defined in the range (44 ÷ 65) °, and the length of the generatrix of the conical element is accepted as not leaving for the radial dimension of the rim of the disk, while the annular fragment of the composite conical diaphragm is equipped with a flange for detachable connection with the canvas of the disk of the third stage, for which holes are made in the flange for fasteners such as tight bolts, spaced around the perimeter of the flange with an angular frequency Y _crepe = (3.82 ÷ 5.25) [units / rad]. 11. The impeller disk of the fourth stage of the HPC rotor according to claim 7, characterized in that the groove of the rim of the disk is made with double broadening in depth, located respectively in the upper and in the bottom parts of the groove and divided by a narrowing formed by two mirror-symmetric mating ring protrusions made with rounded opposed end sections of the profile in the cross section of the groove located at a distance that provides the possibility of supporting the shank of the blade between them, while the lower broadening of the rings the groove of the rim of the disk is made with faces that form a lock configuration of the “annular groove” type with an angle of mutual inclination of the side faces of (91 ÷ 98) °, and congruent with respect to the dominant points of the supporting surfaces to the mating surfaces of the blade root, and the upper groove broadening is made corresponding to configuration, width and axial height difference of the front and back edges of the groove to the axial inclination of the main part of the upper surface area of the root shelf of the scapula, which extends into the flow part, which in turn is made dentichnym desired slope of the inner contour part running at an axial location of the disk portion of the fourth stage HPC. 12. The impeller disk of the fourth stage of the HPC rotor according to claim 7, characterized in that the circumference of the annular groove in the rim of the disk is sufficient to accommodate the shanks of the blades with an angular frequency of Y _l , defined in the range of values of Y _l = (12.73 ÷ 17.52) [units / rad]. 13. The impeller disk of the fourth stage of the HPC rotor according to claim 7, characterized in that the rim of the disk is made with the possibility of detachable connection of the front shelf with the mating rear shelf of the rim of the disk of the third stage, moreover, in the junction area, sections of the shelves of these disks are lapped and fastened along the contour of the power drum-disk shell with fixing elements such as pins. 14. The impeller of the fourth stage as part of the rotor of a multi-stage high-pressure compressor turbofan engine, having a housing with a flowing part, a low-pressure turbine with a shaft, a high-pressure turbine and an HPC rotor, including a drum-disk design shaft, and also having a front support equipped with a trunnion a bell to the specified impeller with a conical diaphragm, characterized in that it contains a blade wreath and a disk endowed with an annular groove for installing the blade blades, and the disk is made in the form of a single element, including UPITs with a central bore, a web and a rim and the blade ring each comprise a shank pen formed with a profile formed concave trough and a convex back, and a root shelf tapered surface on both sides of the pen, the radius R _d disk from the axis the HPC rotor to the conditional conical surface, coaxial with the rotor shaft and describing the upper surface of the rim in the middle radial plane of the web, is (0.67 ÷ 0.93) from the radius R _p.h. the peripheral contour of the flowing part in the specified plane, and the radius R _ts.o.s. the central hole of the hub is sufficient for free passage of the shaft of the theater and optionally component (0.31 ÷ 0.49) from the radius R _{d of the} disk in the middle radial plane of the disk blade; the rim of the disk is divided by an annular groove into two asymmetric, unevenly different annular shoulders, the peripheral sections of the annular shelves of which together with the outer surface of the root flanges of the blades form the sleeve surface of the contour of the engine ducts within the axial length of the rim of the disk of the fourth stage of the HPC rotor, and the outer surface of the rim is made with the angle of inclination of the generatrix relative to the axis of the rotor shaft and the radius increasing in the direction of movement of the flow of the working fluid in the axial section of the HPC with a gradient of G _R. defined in the range

where R _max and R _min - the maximum and minimum radii of the generatrix of the upper surface of the rim of the disk; In _about - the axial width of the rim of the disk, limited by the interscapular channel; in addition, the disk is equipped with an annular conical element in the form of an axisymmetric shell, common or combined with the disk blade, facing the third-stage disk and the transitional annular fragment of the conical diaphragm of the axle of the front support, while the disk rim is made with the possibility of transmitting torque from the TVD shaft detachable connection of the front shelf with the mating flange of the disk of the impeller of the third stage and one-piece connection of the rear shelf with the mating flange of the disk of the fifth stage impeller with the formation of the combined annular portion of the inner contour of the flow passage of the HPC and the double inclusion of the fourth-stage disk into the power shell of the drum-disk construction of the rotor shaft both directly through the rims of the previous disks of the drum-disk shell of the rotor shaft and through the conical diaphragm and the third disk steps. 15. The impeller of the fourth stage of the HPC rotor according to claim 14, characterized in that the blades are evenly spaced around the perimeter of the disk with an angular frequency of Y _l = (12.73 ÷ 17.52) [units / rad]. 16. The impeller of the fourth stage of the HPC rotor according to claim 14, characterized in that for the radial-angle fixation of the position of the blades, the annular groove is made with contact protrusions, the lower face of each of which is located at an angle to the reference plane in the bottom part of the groove, identical to the angle of inclination mating faces towards the blade root shank sole component β ₁ = (29 ÷ 40) °, and the displacement in the circumferential direction in the annular groove of the blade are fixed by at least five retaining elements, which are constructed as a prismatic VC Adyshev configuration in cross section, congruent profile of the annular groove, and are endowed are each threaded through-hole for the fixing screw. 17. The impeller of the fourth stage of the rotor of the HPC according to claim 14, characterized in that the conical ring element of the disk is made with an angle of inclination of the generatrix to the conditional middle plane of the web, identical in magnitude to the angle of inclination of the generatrices of the conical section from the rear shelf of the rim to the disk web and the transition ring a fragment of the conical diaphragm, which is equipped with a flange for power connection with the disk of the impeller of the third stage with the possibility of transmitting torque from the theater, while the angle of inclination of the generatrix of the conical ring the first element of the disk and the conical diaphragm is made variably defined in the range (44 ÷ 65) °, and the length of the generatrix of the conical element is assumed not to exceed the radial dimension of the rim of the disk. 18. The impeller of the fourth stage of the HPC rotor according to claim 14, characterized in that the blade blade is made with an axial twist variable with respect to the rotor axis, increasing with a radial distance from the rotor axis with a feather twist gradient G _z defined in the projection onto the conditional axial plane in range G _s.p. = (α _p -α _k ) / N _sr = (148.2 ÷ 214.4) [deg / m], where α _to - the angle of installation of the profile of the feather blades in the root section; α _p - the same in the peripheral section; N _cf - the average height of the feather blades; in addition, the feather of the blade is made variable in width and height of the feather with a thickness defined in cross section as the difference in height of the back and trough relative to the chord connecting the input and output edges of the feather of the blade, while the maximum thickness of the profile of the feather of the blade is made the largest in the root section and decreases along pen height to the peripheral end. 19. The impeller of the fourth stage of the HPC rotor according to claim 14, characterized in that the annular shelves of the rim of the disk are made protruding beyond the size of the pen of the working blade to a width sufficient to interact along the working fluid with the blades of the stator guide apparatus, while in the joint zone the disk shelves of the third and fourth stages are lapped and fastened along the contour of the power drum-disk shell by fixing elements such as pins. 20. The impeller of the fourth stage as part of the rotor of a multi-stage high-pressure compressor turbofan engine, having a housing with a flowing part, a low-pressure turbine with a shaft, a high-pressure turbine and an HPC rotor, including a drum-disk design shaft, and also having a front support equipped with a trunnion a bell to the specified impeller with a conical diaphragm, characterized in that it contains a blade wreath and a disk endowed with an annular groove for installing the blade blades, and the disk is made in the form of a single element, including a hub with a central hole, a web and a rim, and the crown blades contain, each, a shank, a feather made with a profile formed by a concave trough and a convex back, and a root shelf with a conical surface on both sides of the feather, and the shank of the blade is made with the possibility of installation in the groove of the rim of the disk and has a configuration of the side and supporting surfaces congruent to the profile of the mating surfaces of the groove with the formation of a lock connection of the "annular groove" type and providing an angle α for installing the pen profile to the rotor axis in the projection n and the conditional axial plane of the rotor normal to the axis of the feather of the blade with α _k = (29.4 ÷ 42.2) ° in the root section of the pen, and α _p = (36.8 ÷ 52.9) in the peripheral section of the pen °, in addition, the blade feather is made with an axial twist variable with respect to the rotor axis, increasing with a radial distance from the rotor axis with a pen twist gradient G _zp defined in the range of the projected axial plane G _s.p. = (α _p -α _k ) / N _sr = (148.2 ÷ 214.4) [deg / m], where α _to - the angle of installation of the profile of the feather blades in the root section; α _p - the same in the peripheral section; N _cf - the average height of the feather blades; and the blades are uniformly spaced around the perimeter of the disk with an angular frequency of Y _l = (12.73 ÷ 17.52) [units / rad], and the rim of the disk is divided by an annular groove into two asymmetric uneven annular shoulders, the peripheral sections of the annular shelves of which together with the outer the surface of the root shelves of the blades form a sleeve surface of the contour of the engine ducts within the axial length of the rim of the disk of the fourth stage of the HPC rotor with an angle ϕ of inclination of the outer surface to the axis of the rotor, identical to the outer surface of the root shelf of the blade; to ensure the transmission of torque from the TVD shaft, the disk rim is made with the possibility of detachable connection of the front shelf with the mating disk of the rim of the impeller of the third stage and one-piece connection of the rear shelf with the mating disk of the disk of the impeller of the fifth stage with the formation of the combined annular section of the inner contour of the flow part ; the impeller is made with a ratio of the radius R _{d of the} disk from the axis of the shaft of the HPC rotor to the conditional conical surface describing the upper surface of the rim of the disk in the middle radial plane of the blade web to the average height H _{cf of the} blade profile of the blade component K _d / N _cf = (5 , 1 ÷ 7.4). 21. The impeller of the fourth stage of the HPC rotor according to claim 20, characterized in that the disk is made with a radius R _d from the axis of the HPC rotor to a conditional conical surface coaxial with the rotor shaft and describing the upper surface of the rim in the middle radial plane of the web, component (0 , 67 ÷ 0.93) from the radius R _p.h. the peripheral contour of the flowing part in the specified plane, and the radius R _ts.o.s. the central hole of the hub is sufficient for free passage of the shaft of the theater and optionally component (0.31 ÷ 0.49) from the radius R _{d of the} disk in the middle radial plane of the disk web. 22. The impeller of the fourth stage of the HPC rotor according to claim 20, characterized in that the disk is equipped with a ring conical element in the form of an axisymmetric shell, common or combined with the disk blade facing the disk of the third stage and the transition ring fragment of the conical diaphragm of the axle of the front support with the possibility one-piece power connection with the latter and providing torque transmission from the theater shaft with duplicated inclusion of the fourth-stage disk in the power shell of the drum-disk design of the roto shaft and directly through drive wheels prior drum-circular shell of the rotor shaft and through the tapered aperture and the web drive and the third stage. 23. The impeller of the fourth stage of the HPC rotor according to claim 20, characterized in that for the radial-angle fixation of the position of the blades, the annular groove is made with contact protrusions, the lower face of each of which is located at an angle to the reference plane in the bottom part of the groove, identical to the angle of inclination mating faces towards the blade root shank sole component β ₁ = (29 ÷ 40) °, and the displacement in the circumferential direction in the annular groove of the blade are fixed by at least five retaining elements, which are constructed as a prismatic VC Adyshev configuration in cross section, congruent profile of the annular groove, and are endowed are each threaded through-hole for the fixing screw. 24. The impeller of the fourth stage of the HPC rotor according to claim 20, characterized in that the annular flanges of the disk rim are made protruding beyond the size of the pen of the working blade to a width sufficient to interact along the working fluid with the blades of the stator guide apparatus, while in the joint zone the disk shelves of the third and fourth stages are lapped and fastened along the contour of the power drum-disk shell by fixing elements such as pins.

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