RU2555935C2 - Method of mass production of gas turbine engine and gas turbine engine made using this method - Google Patents

Abstract

FIELD: power industry.

SUBSTANCE: invention relates to power industry. Method of mass production of gas turbine engine under which parts are manufactured, and assembly units, elements and assemblies of modules and engines are completed. At least eight modules are assembled - from LP compressor to all-rating adjustable jet nozzle. Engine is made out of modules, it is made two-circuit, two-shaft. After assemblage the gas turbine engine is tested under at least one of programs - multi-cycle for gas-dynamic stability or for climatic conditions effect on the main engine operation characteristics. Besides the gas turbine engine manufactured according to this method is provided.

EFFECT: invention ensures improved traction, increased authenticity of the operation characteristics of the gas turbine engine, and representation of the test results for various gas-dynamic conditions of the engine operation.

15 cl, 4 dwg

Description

The invention relates to the field of aircraft engine manufacturing, namely to aircraft turbojet engines.

Known double-circuit, twin-shaft gas turbine engine (GTE), including turbocompressor complexes, one of which contains a compressor and a low pressure turbine mounted on one shaft, and the other contains a compressor and a high pressure turbine, an intermediate separation housing, similarly combined on the other shaft, coaxial with the first between the aforementioned compressors, the external and internal circuits, the main and afterburner combustion chambers, a chamber for mixing gas-air flows of the working fluid and an adjustable nozzle (N.N. Siroti and others. Fundamentals of designing the production and operation of aircraft gas turbine engines and power plants in the CALS technology system. Book 1. Moscow, Nauka Publishing House, 2011, pp. 41-46, Fig. 1.24).

Known gas turbine engine, which is a dual-circuit, contains a housing supported by compressors and turbines, a cooled combustion chamber, a fuel pump group, jet nozzles, as well as a control system with command and executive bodies (Design and engineering of aircraft gas turbine engines. Edited by D .V. Chronin. M., Engineering 1989. S. 12-88).

A known method of development and testing of aircraft engines such as gas turbine, including the development of predetermined modes, parameter control and assessment of resource and reliability of the engine. In order to reduce the test time during engine refinement of 10-20%, tests are carried out with the gas temperature in front of the turbine exceeding the maximum operating temperature by 45-65 ° C (SU 1151075 A1, publ. 10.08.2004).

A known method of testing a gas turbine engine, which consists in creating at the entrance to the engine uneven air flow by establishing grids in the inlet channel to determine the boundary of the stable operation of the compressor. To introduce an engine compressor into the surge, a set of grids is required that are installed in the input channel, gradually increasing unevenness, which leads to an increase in the number of starts and time for installing grids in the input channel (Yu.A. Litvinov, VO Borovik. Characteristics and operational properties of aircraft gas turbine engines. Moscow: Mechanical Engineering, 1979, 288 pp., pp. 13-15).

A known bench for testing a turbocharger of an internal combustion engine, which is additionally equipped with an adjustable heater, a second recuperative heat exchanger, a heat exchanger-cooler and an adjustable interceptor, made in the form of a housing with a central channel for gas passage and through holes located along the generatrix of the housing, connected to the atmosphere through controlled valves . An adjustable interceptor is installed at the compressor inlet of the turbocharger under test (RU 2199727 C1, 12/27/2004).

A known method for the development and testing of aircraft gas turbine engines, which consists in measuring the parameters according to the operating modes of the engine and bringing them to standard atmospheric conditions, taking into account changes in the properties of the working fluid and the geometric characteristics of the engine flow part when changing atmospheric conditions (Yu.A. Litvinov, V.O. Borovik. Characteristics and operational properties of aircraft gas turbine engines. Moscow: Mechanical Engineering, 1979, 288 pp., Pp. 136-137).

There is a method of testing a gas turbine engine to determine the resource and reliability, which consists in the alternation of modes when performing stages lasting longer than the flight time. The engine is tested in stages. The duration of non-stop operation at the stand and the alternation of modes are set depending on the purpose of the engine (L. S. Skubachevsky. Test of jet engines. Moscow, Mechanical Engineering, 1972, p.13-15).

The disadvantages of these known technical solutions are the increased labor and energy intensity of tests performed by known methods, and, as a result, the reliability of the assessment of the most important engine parameters in a wide range of operating conditions and conditions is not high enough. The most significant of these drawbacks is the need for multiple engine shutdown during testing and multiple replacement of interceptors with different aerodynamic transparency, creating one degree or another of aerodynamic interference and reducing or increasing the flow of air entering the test engine. The disadvantages of these known technical solutions include the insufficiently high reliability of evaluating engine thrust, service life and reliability of a gas turbine engine in a wide range of flight modes and regional operating conditions, including temperature and climate conditions, due to the inadequacy of the program for bringing specific test results performed at different temperature and climatic conditions, to results attributed to standard atmospheric conditions by known methods,

The objective of the group of inventions related by a single creative idea is to develop a method for the mass production of a gas turbine engine and a gas turbine engine performed by the claimed method with improved performance characteristics, which provide improved traction and increased reliability of operational characteristics for different gas-dynamic situations of engine operation, a wide range of combinations of modes and operation cycles in the range of temperature and climatic conditions characteristic of different regions and operating modes AI engine and to increase the representation of the full range of these conditions occur, the test results in relation to the flight cycle of the engine in training and combat conditions in different regions and seasonal periods of operation.

The problem is solved in that in the method of mass production of a gas turbine engine, according to the invention, parts are made and assembly units, elements and units of engine modules and systems are completed; modules are assembled in an amount of at least eight - from a low-pressure compressor (LPC) to an all-mode adjustable jet nozzle; in the process of manufacturing KND, a stator is assembled, in which an input, not more than three intermediate guide vanes and an output straightener are installed, and also a rotor is assembled, including a shaft, on which no more than four impellers are mounted and rigidly connected by disks to the blade system, and annular sections of the inner surface of the intake channel of the KND flowing section from elements of the impeller vanes and KND guiding devices profiled in the direction of the air flow; preferably, modularly, an engine is assembled, which is performed by a double-circuit, two-shaft, while an intermediate case is mounted on the technological slipway; a gas generator, including a high pressure compressor (HPC), having a stator including an input, not more than eight intermediate guide vanes and an output straightening device, as well as a rotor with a shaft and a system of impellers equipped with vanes, the number of which is at least two times the number mentioned KND impellers, main combustion chamber and high pressure turbine (HPT); then, in front of the intermediate casing, low pressure valves are installed, and behind the gas generator, a low pressure turbine (low pressure turbine), mixer, front-end device, afterburner, and an all-mode jet nozzle are sequentially coaxially installed; in addition, in the process of manufacturing the low pressure switch, the input guide vane (VNA) is equipped with an aerodynamically transparent power grid of radial struts, which establish a uniform distribution around the inlet section of the VNA, mainly in the plane normal to the axis of the engine, with an angular frequency (3.0 ÷ 4.0) units / rad and with aerodynamic shading created by the aforementioned lattice together with the frontal VNA coke, which is less than 30% of the total area of the inlet circle, outlined by the external radius of the VNA flowing part; moreover, after assembly, the engine was tested in at least one of the programs: on gas-dynamic stability, on the influence of climatic conditions on operational characteristics, as well as on determining the engine resource by a multi-cycle program.

During installation, the axis of the adjustable jet nozzle can be executed deviated down from the neutral position of the engine axis by an angle of (2 ° ÷ 3 ° 30 ′).

The intermediate housing can be endowed with the function of a power unit of the engine with the possibility of perceiving the total axial and radial loads from compressors and turbines with subsequent transmission to external power elements and is installed between the low pressure switch and the high pressure switch, dividing the air coming from the low pressure switch into two flows - external and internal circuits, while in the outer circuit around the body of the main combustion chamber, an annular air-air heat exchanger is assembled from at least sixty tubular block modules, and above the intermediate casing on the outer Engine sensor body mounted box drive motor units.

The inlet guide apparatus of the low-pressure compressor can preferably be equipped with twenty-three radial racks connecting the outer and inner BHA rings with the possibility of transferring loads from the external engine casing to the front support, and the radial racks are made up of a fixed hollow and controllable movable elements, while at least part of the radial racks are combined with the channels of the oil system located in the stationary elements of the racks, with the possibility of supply and removal of oil, and that the venting and oil predmaslyanyh cavities front low pressure compressor rotor bearing.

During the installation process, it is preferable that they can detach KND and HPD along the rotor shaft with the possibility of transmitting torque to the compressor from the specified turbine, and KVD similarly combine with the HPT to form a common KVD-TVD rotor shaft with the possibility of receiving torque by the high pressure compressor from the specified turbine high pressure.

The rotor shaft KVD-TVD can be made with a larger diameter and shorter than the combined shaft KND-TND, at least for the total axial length of the intermediate housing, the main combustion chamber and the high pressure pump and set with coaxial coverage of the latter with the possibility of independent rotation of these shafts.

Cases of the external and internal circuits of the engine can be mounted in fragments with the possibility of partial combination with the installation of air, electric, hydraulic systems and a control system, while in the air system there are allocated cooling subsystems for overheated units, as well as anti-icing heating VNA KND, pressurization subsystems for compressor rotors and turbines .

The VNA anti-icing heating subsystem can be communicated with the HPC by the heated air intake channel with the possibility of taking the latter from the cavity located at least behind the seventh impeller of the specified compressor.

After assembly, the engine can be tested at least to determine the gas-dynamic stability (GDU) of a serial gas turbine engine, for this purpose at least one is randomly selected, for representativeness, preferably three to five gas turbine engines from a serial batch, the test engine is placed on a bench with an aerodynamic inlet device, which is equipped with an adjustable crossover air flow, mainly a remotely controlled retractable interceptor with a graduated scale of interceptor positions in the flow of air supplied to the engine having a fixed critical point separating the engine by 2-5% from the transition to surge; repeat the tests on a set of modes defined by the regulations corresponding to the modes characteristic of the subsequent real work of the gas turbine engine in flight conditions; experimentally confirm the area of gas-dynamic stability of operation and, at least in the mode with the least margin of gas-dynamic stability, perform counter-throttle response according to the regulations: holding at maximum speed, resetting the speed by setting the engine control lever to the "low gas" position, and when the frequency value is reached rotation corresponding to the value of the developed unevenness, perform engine throttle response to maximum mode by translating the engine control lever into Proposition "maximum speed" and define reserves dynamic stability of the engine compressor.

During the tests, they can experimentally confirm the area of gas-dynamic stability of the engine, including for the regime with the smallest reserve of the GDU with on-board throttle response, checked according to the regulations: shutter speed at maximum speed, resetting the speed by setting the engine control lever to the "low gas" position and in phases frequency of rotation corresponding to the values of intermediate irregularities with a check of engine throttle response to maximum mode when the engine control lever is set to " Maximum Feed turnovers' with a resultant determination of dynamic stability inventory engine compressor.

Alternatively, after assembly, the engine can be tested at least to assess the influence of climatic conditions (VKU) on the change in the operational characteristics of a serial gas turbine engine; for this purpose, at least one should be subjected to representativeness, preferably three to five mass-produced gas turbine engines; GTE tests are carried out in various modes, the parameters of which correspond to the parameters of flight modes in the range programmed for a specific series of engines, measure and bring the obtained values of the parameters to standard atmospheric conditions, taking into account changes in the properties of the working fluid and the geometric characteristics of the flow part of the GTE with changing atmospheric conditions at the same time, the mathematical model of the gas turbine engine is preliminarily created, and it is adjusted according to the results of bench tests representative from three to five identical gas-turbine engines, and then, using the mathematical model, gas-turbine engine parameters are determined under standard atmospheric conditions and various atmospheric air temperatures from a given operating temperature range of bench tests taking into account the adopted engine control program at maximum and forced modes, and the actual values of the parameters specific atmospheric air temperatures of each test mode are referred to parameter values under standard atmospheric conditions and correction coefficients for the measured parameters depending on the atmospheric air temperature are adjusted, and the measured parameters are brought to standard atmospheric conditions by multiplying the measured values by coefficients that take into account the deviation of the atmospheric pressure from the standard one and by a correction factor reflecting the dependence of the measured parameter values on the atmospheric air temperature, registered in specific tests of a gas turbine engine.

After assembling at least one gas turbine engine from a batch of serial gas turbine engines, for representativeness, preferably three to five engine instances can be tested using a multi-cycle program, this test program includes alternating modes during the test stages with a gas turbine operation duration exceeding the programmed flight time, why first form typical flight cycles and determine the damageability of the most loaded parts, on the basis of this determine the required number of loading cycles tests during the test, and then form and produce the full scope of the tests, including the execution of the sequence of test cycles - quick exit to the maximum or full forced mode, quick reset to the "low gas" mode, stop and long-term operation cycle with multiple alternating modes in the entire operating spectrum with a different range of changes in the operating modes of a gas turbine engine, in total exceeding the flight time by 5-6 times; at the same time, a different range of changes in the engine operating modes is realized by changing the level of the gas differential in specific test modes from the initial to the maximum - maximum or full forced engine operation by transferring the initial reference point when performing the corresponding mode, taking the latter in one of the modes in position the corresponding “low gas” level, and in other modes - in intermediate or final positions corresponding to different percentages or the full value of the level gas of maximum or full forced mode, and a quick exit to maximum or forced modes on part of the test cycle is carried out at a rate of pick-up with subsequent reset.

Part of the test cycles can be carried out without warming up in the "low gas" mode after starting.

The test cycle can be formed on the basis of flight cycles for combat and training use of a gas turbine engine.

The problem in part of the gas turbine engine is solved by the fact that the gas turbine engine according to the invention is made as described above.

The technical result provided by the group of inventions related by a single creative idea, given a set of features, consists in developing a method for the mass production of a gas turbine engine and a gas turbine engine made by the claimed method with the combination of the main gas turbine engine modules with improved operational characteristics, namely, a more reliable determination of the boundaries of the possible thrust variation within the acceptable range of gas-dynamic stability of compressor operation, with increased p LAS-cycle engine under engine operation by varying the frequency spectrum and duration of operation of the engine thrust, as well as increased reliability and resource experimentally proven reliability of the engine in conditions close to the actual structure and the ratio of specific engine operating conditions during operation. This is achieved through the use of a combination of the basic modules developed in the invention with the declared parameters and technical solutions, namely, low pressure, high pressure, high pressure and high pressure and turbines. Improving the reliability of the assessment of the GDU is provided by the test system developed in the invention, conducted at the industrial production stage, with a retractable aerodynamic device interceptor, and a test program that excludes the introduction of the engine into the surge. Similarly, the programs of multi-cycle tests and tests developed at the indicated stage on the influence of climatic conditions on changes in the main characteristics developed in the invention provide an increase in the accuracy of evaluating the resource and engine operation parameters in various temperature and climatic conditions of operation in regions with different climates.

The invention is illustrated by drawings, where:

figure 1 shows a gas turbine engine, a longitudinal section;

figure 2 - input device of an aerodynamic installation for testing an engine equipped with an interceptor, side view;

Figure 3 - a section along A-A in Figure 2, _and where H - the height of the spoiler, D _kan - the diameter of the channel of the input device;

figure 4 - input guide apparatus of the low-pressure compressor, top view.

The method of mass production of a gas turbine engine is used to make parts and complete assembly units, elements and units of engine modules and systems. Then, at least eight modules are assembled - from the low-pressure compressor 1 to the variable-speed adjustable jet nozzle 2. In the process of manufacturing KND 1, a stator is assembled, in which an input guide device 3, no more than three intermediate guide devices 4 and an output rectifier 5 are installed. A rotor is also assembled, including a shaft 6, on which no more than four impellers 7 are mounted and rigidly connected by disks to a system of blades 8. Moreover, from the bladed elements 8 profiled in the direction of air flow the impellers 7 and the blades of the intermediate guide vanes 4 form the annular sections of the inner surface of the air intake channel 9 of the flow part of the KND 1.

The engine is preferably assembled modularly. TDR perform double-circuit, two-shaft. In this case, an intermediate casing 10 is installed on the technological slipway, forming a high pressure compressor 11 as a gas generator, as well as a main combustion chamber 12 and a high pressure turbine 13. The high-pressure compressor 11 includes a stator, as well as a rotor with a shaft 14 and a system of impellers 16 equipped with vanes 15.

The stator KVD contains an input guide vane 17, no more than eight intermediate guide vanes 18 and an output straightener 19. The number of impellers 16 of the high pressure transformer 11 is at least twice the number of impellers 7 of the low pressure switch 1. Before the intermediate casing 10, the low pressure switch 1 is installed, and behind the gas generator, a low pressure turbine 20, a mixer 21, a frontal device 22, an afterburner 23 of the combustion and an all-mode jet nozzle 2 are sequentially coaxially mounted.

In the process of manufacturing KND 1, the input guide apparatus 3 is equipped with an aerodynamically transparent power grid of radial struts 24. Radial racks 24 connect the outer and inner rings 25 and 26, respectively, of the VNA 3 with the possibility of transferring loads from the outer case 27 of the engine to the front support. Radial struts 24 are installed uniformly distributed around the inlet section of the BHA 3, mainly in the plane normal to the axis of the engine, with an angular frequency (3.0 ÷ 4.0) u / rad, and with aerodynamic shading created by the above-mentioned grill together with the front Coke 28 VNA, comprising less than 30% of the total area of the input circle, outlined by the external radius of the flow part of the VNA 3.

After assembly, the engine was tested in at least one of the programs: gas-dynamic stability, the influence of climatic conditions on operational characteristics, and also on the determination of the engine resource by a multi-cycle program.

During installation, the axis of the adjustable jet nozzle 2 is executed deflected down from the neutral position of the axis of the engine at an angle of (2 ° ÷ 3 ° 30 ′).

The intermediate housing 10 is endowed with the function of a power unit of the engine with the possibility of perceiving the total axial and radial loads from compressors 1, 11 and turbines 13, 20 with subsequent transmission to external power elements and is installed between KND 1 and KVD 11, dividing the air coming from the KND into two streams - outer and inner circuits 29 and 30, respectively. An annular air-to-air heat exchanger 31 is assembled in an outer loop 29 around the body of the main combustion chamber 12 from at least sixty tubular block modules. A drive box of motor units is installed over the intermediate case 10 on the outer case 27 of the engine (not shown).

The input guide device 3 KND 1 preferably contains twenty-three radial racks 24, consisting of a fixed hollow and controlled movable elements. At least part of the radial struts 24 are combined with the channels of the oil system located in the stationary elements of the racks, with the possibility of supplying and discharging oil, as well as venting the oil and pre-oil cavities of the front support of the KND 1 rotor.

During the installation process, it is preferable to detach the KND 1 with the low pressure pump 20 along the rotor shaft 6 with the possibility of transmitting to the compressor 1 torque from the specified turbine 20. KVD 11 similarly combine with the theater 13 to form a common shaft 14 of the KVD-TVD rotor with the possibility of obtaining torque high pressure compressor 11 from high pressure turbine 13.

Moreover, the shaft 6 of the rotor KVD-TVD is made with a larger diameter and shorter than the combined shaft 14 KND-TND, at least for the total axial length of the intermediate housing 10, the main combustion chamber 12 and the pressure pump 20 and set with a coaxial coverage of the latter with the possibility of autonomous rotation of these shafts 6 and 14.

Cases of the external and internal circuits of the engine are mounted in fragments with the possibility of partial combination with the installation of air, electric, hydraulic systems and control systems. In the air system, the cooling subsystems of the overheated units are distinguished, as well as the anti-icing heating of the inlet guide apparatus 3 KND 1, the pressurization subsystem of the supports of the compressor rotors and turbines.

The VNA 3 anti-icing heating subsystem is communicated with the HPA 11 with a heated air intake channel (not shown in the drawings) with the possibility of taking the latter from the cavity located at least behind the seventh impeller 16 of the HPA 11.

After assembly, the engine is tested at least to determine the gas-dynamic stability of the serial gas turbine engine. To do this, at least one is randomly selected for representativeness, preferably three to five gas turbine engines from a batch produced. The test engine is placed on a bench with an inlet aerodynamic device 32. The device 32 is equipped with a variable-crossover air flow, mainly remotely controlled by a retractable interceptor 33 with a graduated scale of the position of the interceptor in the air supply to the engine, having a fixed critical point separating the engine by 2-5% from going to surge. The tests are repeated on a set of modes defined by the regulations corresponding to the modes characteristic of the subsequent real work of the gas turbine engine in flight conditions. Experimentally confirm the area of gas-dynamic stability of work and, at least in the mode with the smallest margin of gas-dynamic stability, they perform counter throttle response according to the regulations: shutter speed at maximum speed, resetting the speed by setting the engine control lever to the "low gas" position. Upon reaching the value of the rotational speed corresponding to the value of the worked out non-uniformity, engine throttle response is performed to the maximum mode by shifting the engine control lever to the “maximum speed” position and determining the gas-dynamic stability reserves of the engine compressor.

When testing experimentally confirm the area of gas-dynamic stability of the engine, including for the regime with the smallest margin GDU with counter throttle response checked according to the regulations: shutter speed at maximum speed, resetting the speed by setting the engine control lever to the "low gas" position and in the frequency phases rotation corresponding to the values of intermediate irregularities with checking engine throttle response to maximum mode when the engine control lever is set to “max “high revolutions” with the resulting determination of the reserves of gas-dynamic stability of the engine compressor.

After assembly, the engine is tested, at least, to assess the impact of climatic conditions on the change in the operational characteristics of a serial gas turbine engine.

To do this, test at least one for representativeness, preferably three to five mass-produced GTE specimens.

GTE tests are carried out in various modes. The parameters of the modes are adequate to the parameters of the flight modes in the range programmed for a specific series of engines. Measurements are made and the obtained parameter values are brought to standard atmospheric conditions, taking into account changes in the properties of the working fluid and geometric characteristics of the flowing part of a gas turbine engine when atmospheric conditions change.

Based on the results of bench tests, they create a mathematical model of a gas turbine engine and correct it. Then, according to a mathematical model, the parameters of the gas turbine engine and various atmospheric air temperatures are determined from the given operating temperature range of bench tests, taking into account the adopted engine control program at maximum and forced modes. The actual values of the parameters at specific atmospheric air temperatures of each test mode are related to the values of the parameters under standard atmospheric conditions and correction factors are calculated for the measured parameters depending on the temperature of the atmospheric air. Bringing the measured parameters to standard atmospheric conditions is carried out by multiplying the measured values by coefficients that take into account the deviation of atmospheric pressure from the standard, and by a correction factor that reflects the dependence of the measured values of the parameters on the temperature of the atmospheric air recorded during specific tests of the gas turbine engine.

After assembling at least one gas turbine engine from a batch of commercially available gas turbine engines for representativeness, preferably three to five engine instances are tested in a multi-cycle program. The specified test program includes the alternation of modes when performing the stages of the test with a duration of gas turbine operation exceeding the programmed flight time. Why first form typical flight cycles and determine the damage to the most loaded parts. Based on this, the required number of loading cycles during the test is determined. Then the full scope of the tests is formed and performed, including the execution of the sequence of test cycles — quick exit to the maximum or full forced mode, quick reset to the “low gas” mode, stop and long-term operation cycle with repeated alternation of modes in the entire working spectrum with a different range of variation operating modes of a gas turbine engine, in total, exceeding the flight time by 5-6 times. A different range of changes in the engine operating modes is realized by changing the level of the gas differential in specific test modes from the initial to the maximum - maximum or full forced engine operation by transferring the initial reference point when performing the corresponding mode, taking the latter in one of the modes in the position corresponding to the level "Small gas". In other modes - in intermediate or final positions corresponding to different percentages or the full value of the gas level of the maximum or full forced mode. A quick exit to the maximum or forced modes on the part of the test cycle is carried out at the rate of throttle response, followed by reset.

Part of the test cycles is carried out without warming up in the "low gas" mode after starting.

The test cycle is formed on the basis of flight cycles for combat and training use of a gas turbine engine.

The gas turbine engine is made by the production method described above.

An example of the implementation of a gas turbine engine test according to one of the programs, namely, a gas turbine engine gas turbine engine stability test.

At the stage of mass production after the assembly of the TDR, a double-circuit engine with a minimum design gas-dynamic stability at a rotor speed of 0.8 Max is tested, where Max is the maximum permissible rotor speed of this engine.

The engine is mounted on a test bench and is communicated with the aerodynamic inlet device 32 through the flange 34. The device 32 is equipped with an adjustable-controlled retractable interceptor 33, mounted with the possibility of crossing the air flow supplied to the engine. The interceptor 33 is configured to create unevenness and control the amount of air entering the engine in the range from 0 to 100% by zero, intermediate or complete overlap of the working section area of the input aerodynamic device 32. For this, the interceptor 33 is equipped with an electric drive containing a drive rod 35 with a hydraulic cylinder 36 , and the extension scale of the interceptor 33, graduated in increments of 1% of the inlet cross-sectional area of the air flow supplied to the engine.

The tested gas turbine engine is brought to the rotor rotation modes from “small gas” (MG) to Max with a step of changing revolutions from mode to 0.05 Max mode and with a sequential iteration to the boundary of loss of gas-dynamic stability. To do this, on each of the modes, the interceptor 33 is successively extended into the air flow section with a step of (1-5)% of the area of the specified section, bringing to the sign of surge. As a result of this test phase, the boundary value of the rotor speed with a minimum margin of gas-dynamic stability is determined, which is 0.8 Max when the interceptor 33 is extended by 73%.

Then, by backward movement of the interceptor 33 in the range of up to 7% of the maximum position at which a surge occurred with a loss of gas-dynamic stability, it is established that when the interceptor 33 is shifted by 5%, there are no signs of surge, the engine is running stably.

An analysis of the test results is carried out, taking into account that the resulting tests were performed without disruption in surging with the maximum introduction of the interceptor 33 at the rotor revolutions, creating a minimum margin of stability, the gas-dynamic stability of this type of gas turbine engine is established in the full range of engine rotor revolutions.

Claims (15)

1. The method of mass production of a gas turbine engine (GTE), characterized in that they manufacture parts and complete assembly units, elements and units of engine modules and systems; modules are assembled in an amount of at least eight - from a low-pressure compressor (LPC) to an all-mode adjustable jet nozzle; in the process of manufacturing KND, a stator is assembled, in which an input, not more than three intermediate guide vanes and an output straightener are installed, and also a rotor is assembled, including a shaft, on which no more than four impellers are mounted and rigidly connected by disks to the blade system, and annular sections of the inner surface of the intake channel of the KND flowing section from elements of the impeller vanes and KND guiding devices profiled in the direction of the air flow; preferably, modularly, an engine is assembled, which is performed by a double-circuit, two-shaft, while an intermediate case is mounted on the technological slipway; a gas generator, including a high pressure compressor (HPC), having a stator including an input, not more than eight intermediate guide vanes and an output straightening device, as well as a rotor with a shaft and a system of impellers equipped with vanes, the number of which is at least two times the number mentioned KND impellers, main combustion chamber and high pressure turbine (HPT); then, in front of the intermediate casing, low pressure valves are installed, and behind the gas generator, a low pressure turbine (low pressure turbine), mixer, front-end device, afterburner, and an all-mode jet nozzle are sequentially coaxially installed; in addition, in the process of manufacturing the low pressure switch, the input guide vane (VNA) is equipped with an aerodynamically transparent power grid of radial struts, which establish a uniform distribution around the input section of the VNA, mainly in the plane normal to the axis of the engine, with an angular frequency (3.0 ÷ 4 , 0) units / rad and with aerodynamic shading created by the aforementioned lattice together with the frontal VNA coke, which is less than 30% of the total area of the inlet circle outlined by the external radius of the VNA flowing part; moreover, after assembly, the engine was tested in at least one of the programs: on gas-dynamic stability, on the influence of climatic conditions on operational characteristics, as well as on determining the engine resource by a multi-cycle program. 2. The method of mass production of a gas turbine engine according to claim 1, characterized in that during installation, the axis of the adjustable jet nozzle is angled (2 ° ÷ 3 ° 30 ′), which is deviated downward from the neutral position of the engine axis. 3. The method of mass production of a gas turbine engine according to claim 1, characterized in that the intermediate casing is endowed with the function of a power unit of the engine with the possibility of perceiving the total axial and radial loads from compressors and turbines with subsequent transmission to external power elements and installed between the low-pressure and high-pressure pumps, sharing air coming from the low pressure switch into two flows - the external and internal circuits, while at least sixty tubular block modules are collected in the outer circuit around the main combustion chamber body howling air-air heat exchanger, and above the intermediate casing on the outer casing of the engine set the drive box of the motor units. 4. The method of mass production of a gas turbine engine according to claim 1, characterized in that the inlet guide apparatus of the low pressure compressor is equipped with, preferably, twenty-three radial posts connecting the outer and inner rings of the BHA with the possibility of transferring loads from the outer engine casing to the front support, radial racks are made up of fixed hollow and controllable movable elements, at least part of the radial racks are combined with the channels of the oil system, size ennymi a fixed member racks for supplying and discharging oil, and also venting and oil predmaslyanyh cavities front low pressure compressor rotor bearing. 5. The method of mass production of a gas turbine engine according to claim 1, characterized in that during the installation process, it is preferable to detach the LPC and the LPC along the rotor shaft with the possibility of transmitting to the compressor the torque from the specified turbine, and the HPC similarly combine with the theater to form a common shaft rotor KVD-TVD with the possibility of obtaining torque by a high pressure compressor from the specified high pressure turbine. 6. The method of mass production of a gas turbine engine according to claim 5, characterized in that the rotor shaft of the HPH-TVD is performed with a larger diameter and shorter than the combined shaft of the HPH-HPH at least by the total axial length of the intermediate housing, the main combustion chamber and TND and set with coaxial coverage of the latter with the possibility of autonomous rotation of these shafts. 7. The method of mass production of a gas turbine engine according to claim 3, characterized in that the cases of the external and internal circuits of the engine are mounted in fragments with the possibility of partial combination with the installation of air, electrical, hydraulic systems and a control system, while the cooling system allocates cooling subsystems for overheated units as well as the anti-icing heating of the high-pressure switch of the low pressure switch, the pressurization subsystem of the bearings of the compressor rotors and turbines. 8. The method of mass production of a gas turbine engine according to claim 7, characterized in that the subsurface anti-icing heating VNA is communicated with the HPC by a heated air intake channel with the possibility of taking the latter from the cavity located at least behind the seventh impeller of the specified compressor. 9. The method of mass production of a gas turbine engine according to claim 1, characterized in that after assembly, the engine is tested for at least gas dynamic stability (GDU) operation of a serial gas turbine engine, at least one of them is randomly selected for representativeness, preferably , three to five gas turbine engines from a batch produced in series, the test engine is placed on a bench with an aerodynamic inlet device, which is equipped with a variable-speed crossover, mainly remotely controlled a retractable interceptor with a graduated scale of the positions of the interceptor in the flow of air supplied to the engine, having a fixed critical point separating the engine by 2-5% from the transition to the surge; repeat the tests on a set of modes defined by the regulations corresponding to the modes characteristic of the subsequent real work of the gas turbine engine in flight conditions; experimentally confirm the area of gas-dynamic stability of operation and, at least in the mode with the least margin of gas-dynamic stability, perform counter-throttle response according to the regulations: holding at maximum speed, resetting the speed by setting the engine control lever to the "low gas" position, and when the frequency value is reached rotation corresponding to the value of the developed unevenness, perform engine throttle response to maximum mode by translating the engine control lever into Proposition "maximum speed" and define reserves dynamic stability of the engine compressor. 10. The method of mass production of a gas turbine engine according to claim 9, characterized in that during the tests experimentally confirm the area of gas-dynamic stability of the engine, including for the regime with the smallest margin of the GDU with on-board throttle response, tested at the maximum shutter speed, frequency reset rotation by setting the engine control lever to the “low gas” position and in the phases of the rotation frequency corresponding to the values of intermediate irregularities with a check of engine throttle response the maximum mode when the engine control lever in the position "maximum speed" with the resultant determination stocks dynamic stability of the engine compressor. 11. The method of mass production of a gas turbine engine according to claim 1, characterized in that after assembly the engine is tested for at least an assessment of the influence of climatic conditions (VKU) on changing the operational characteristics of a serial gas turbine engine, for which at least one is subjected to representativeness preferably three to five mass-produced specimens of a gas turbine engine; GTE tests are carried out in various modes, the parameters of which correspond to the parameters of flight modes in the range programmed for a specific series of engines, measure and bring the obtained values of the parameters to standard atmospheric conditions, taking into account changes in the properties of the working fluid and the geometric characteristics of the flow part of the GTE with changing atmospheric conditions at the same time, the mathematical model of the gas turbine engine is preliminarily created, and it is adjusted according to the results of bench tests representative from three to five identical gas-turbine engines, and then, using the mathematical model, gas-turbine engine parameters are determined under standard atmospheric conditions and various atmospheric air temperatures from a given operating temperature range of bench tests taking into account the adopted engine control program at maximum and forced modes, and the actual values of the parameters specific atmospheric air temperatures of each test mode are referred to parameter values under standard atmospheric conditions and correction coefficients for the measured parameters depending on the atmospheric air temperature are adjusted, and the measured parameters are brought to standard atmospheric conditions by multiplying the measured values by coefficients that take into account the deviation of the atmospheric pressure from the standard one and by a correction factor reflecting the dependence of the measured parameter values on the atmospheric air temperature, registered in specific tests of a gas turbine engine. 12. The method of mass production of a gas turbine engine according to claim 1, characterized in that after assembly of at least one gas turbine engine from a batch of mass-produced gas turbine engines for representativeness, preferably three to five engine instances are tested according to a multi-cycle program, said test program includes alternating modes when performing the stages of the test with a gas turbine engine operating duration exceeding the programmed flight time, for which typical flight cycles are first formed and the damageability of the most loaded hoists, based on this, determine the required number of loading cycles during the test, and then form and produce the full scope of the tests, including the execution of the sequence of test cycles - quick exit to the maximum or full forced mode, quick reset to the "low gas" mode, stop and long cycle work with multiple alternation of modes in the entire working spectrum with a different range of changes in the operating modes of a gas turbine engine, in total exceeding the flight time by 5-6 times; at the same time, a different range of changes in the engine operating modes is realized by changing the level of the gas differential in specific test modes from the initial to the maximum - maximum or full forced engine operation by transferring the initial reference point when performing the corresponding mode, taking the latter in one of the modes in position the corresponding “low gas” level, and in other modes - in intermediate or final positions corresponding to different percentages or the full value of the level gas of maximum or full forced mode, and a quick exit to maximum or forced modes on part of the test cycle is carried out at a rate of pick-up with subsequent reset. 13. The method of mass production of a gas turbine engine according to item 12, characterized in that part of the test cycles is carried out without heating in the "small gas" mode after starting. 14. The method of mass production of a gas turbine engine according to item 12, characterized in that the test cycle is formed on the basis of flight cycles for combat and training use of a gas turbine engine. 15. A gas turbine engine, characterized in that it is made according to any one of claims 1 to 14.

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