RU2550999C1 - Method of operational development of experimental jet turbine engine - Google Patents

Abstract

FIELD: engines and pumps.

SUBSTANCE: invention relates to air-engine building, namely to air turbojets. The experimental double-circuit, two-shaft GTE is subjected to operational development. Operational development of TJE is performed step by step. At each phase from one to five TJEs are tested for compliance with the pre-set parameters. At an operational development phase the experimental TJE is tested according to the multi-cycle program. When performing the test steps, alteration of the modes, which exceed as to duration the configured flight time, is performed. Typical flight cycles are formed, based on which damageability of the most loaded parts is determined as per the programme. The required number of loading cycles during the test is determined based on the named above. Full scope of tests is formed, including a quick change of cycles in the complete register from quick selection of maximum or full augmented power mode till complete stop of the engine, and then, representative cycle of continuous operation with multiple alteration of modes in the whole working spectrum with various span of range of the mode change, which exceeds the flight time at least 5 times. Quick selection of maximum or augmented power mode in some part of the test cycle is performed at the rate of acceleration and discharge.

EFFECT: improvement of reliability of tests results at the phase of operational development of experimental TJEs and expansion of a representativeness of resource assessment and reliability of operation of TJEs in the wide range of regional and seasonal conditions of the subsequent flight operation of engines.

6 cl, 2 dwg

Description

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

Known dual-circuit, twin-shaft turbojet engine (turbojet engine), 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 mentioned compressors, 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.Siro tin et al. Fundamentals of designing the production and operation of aviation gas turbine engines and power plants in the CALS technology system. Book 1. Moscow, Nauka publishing house, 2011, pp. 41-46, Fig. 1.24).

A well-known turbojet engine, which is double-circuit, contains a housing supported by compressors and turbines, a cooled combustion chamber, a fuel-pump group, jet nozzles, and a control system with command and executive bodies (Shulgin V.A., Gaysinsky S.Ya Double-circuit turbojet engines of low-noise aircraft. M., ed. Mashinostroenie, 1984, pp. 17-120).

There is a method of testing a turbojet 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).

A known method of testing aircraft engines of the turbojet type, including the development of predetermined modes, monitoring parameters and evaluating them 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).

Common disadvantages of these known technical solutions are the increased labor and energy intensity of tests and insufficiently high assessment of the resource and reliability of the engine in a wide range of flight modes and operating conditions due to the inadequacy of the program to bring specific test results to the results referred to standard engine operating conditions by known methods, which with sufficient accuracy, do not take into account changes in the parameters and operating modes of the engine. This complicates the possibility of bringing the experimental test parameters to parameters that are as close as possible to the real structure and the specific ratio of the engine operating modes during operation.

The objective of the invention is to develop a method for fine-tuning an experimental turbojet engine with improved performance and increased reliability of an experimentally tested resource and engine reliability under conditions as close as possible to the real structure and specific ratio of engine operating modes during operation.

The problem is solved in that in the method of refining an experimental turbojet engine according to the invention, an experimental engine is subjected to refinement, made by double-circuit, twin-shaft, while the engine is refined in stages, for which a program and algorithms for refining tests of an experimental turbojet engine are developed; at each stage, they are tested for compliance with the specified parameters with a statistically representative amount, mainly from one to five copies, and a condition is examined of each tested from the mentioned number of copies of the experimental engine; for analysis and assessment of the condition, if necessary, disassemble, followed by possible refinement and / or replacement of parts of any of the modules and / or components of the experimental engine, inspect and, if necessary, replace any of the modules damaged in the tests or inadequate with the required parameters, including a low compressor pressure (KND) with an input guide vane (VNA) containing radial power racks consisting of a stationary hollow and controllable movable elements and uniformly spaced the inlet section of bone with an angular frequency within a range of accommodation racks (3,0 ÷ 4,0) U / rad, and the rotor shaft, preferably containing not more than four impellers with vanes system; a gas generator including assembly units — an intermediate casing, a high pressure compressor, a main combustion chamber and a high pressure turbine; sequentially located behind the gas generator, coaxially mounted low-pressure turbine; mixer; a front-mounted device, a combustion afterburner and an all-mode rotary jet nozzle, including a rotary device, preferably detachably attached by a fixed element to the afterburner, and an adjustable jet nozzle similarly attached to the movable element of the rotary device with the possibility of making turns to change the direction of the thrust vector; as well as an air-air heat exchanger module installed above the main combustion chamber in the external circuit, if necessary, inspecting any of at least sixty tubular block modules of the latter, in addition, they inspect and produce the necessary refinement of the motor unit drive box (KDA) and combining these modules electric, pneumatic, hydraulic - fuel and oil systems, including, if necessary, replacing sensors, command blocks, actuators and cables of diagnostic systems and av engine control; at the same time, the experimental turbojet engine is refined, the axis of rotation of the indicated rotary device of the jet nozzle of which is made rotated relative to the horizontal axis by an angle of at least 30 °, preferably (32 ÷ 34) ° clockwise (NP view) for the right engine and at an angle of at least 30 °, preferably at (32 ÷ 34) ° counterclockwise (NP view) for the left engine; at the same time, at the stage of debugging, not less than one, preferably the aforementioned representative number of copies of the experimental turbojet engine is subjected to a multi-cycle test; the specified test program includes the alternation of modes when performing test phases with a turbofan engine operating longer than the programmed flight time, for which typical flight cycles are first formed and the damageability of the most loaded parts is determined, based on this, the required number of loading cycles is determined during the test, and then the full cycle is formed and produced scope of tests, including the execution of a sequence of test cycles - quick exit to maximum or full forced mode, fast resetting to the “low gas” mode, stopping and a long operation cycle with multiple alternating modes in the entire operating spectrum with a different range of variation in the operating modes of a turbojet engine, which in aggregate exceeds the flight time by 5-6 times; at the same time, a different range of changes in the operating modes of the turbojet engine is realized by changing the level of the gas differential in specific test modes from the initial to the maximum - maximum or full forced mode of the turbojet engine by transferring the initial reference point when the corresponding mode is executed, taking the latter in one of the modes in position corresponding to the “small gas” level, and in other modes - in intermediate or final positions corresponding to different percentages or the full value of the maxim gas level full or forced mode, moreover, a quick exit to the maximum or forced modes on part of the test cycle is carried out at the rate of acceleration followed by reset, after which the subsequent stages of testing and fine-tuning the turbojet engine are carried out in an amount necessary and sufficient to bring the engine into a condition suitable for transmission bearer or state trials.

As part of communication systems, they can refine the air system, highlighting the subsystems for cooling the overheated units, the anti-icing heating of the VNA engine and the pressurization subsystem for the bearings of the compressor and turbine rotors.

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 turbojet engines.

A prototype engine may be fine-tuned, the BHA of the LPC which preferably contains twenty-three radial struts connecting the outer and inner rings of the BHA with the possibility of transferring loads from the external engine casing to the front support, and at least part of the struts is aligned with the channels of the oil system located in fixed 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 low pressure rotor.

Finishing can be subjected to an experimental turbojet engine, the frontal area of the input opening F _{I. etc.} VNA KND which geometrically defines the cross section of the inlet mouth of the air intake channel, bounded at a larger radius by the inner contour of the outer ring of the VHA, and at a smaller radius by the inner contour of the inner ring of the VNA, is larger than the total aerodynamic shading area F _c created by the frontal projection of the coke and radial racks, (2.54 ÷ 2.72) times and is (0.67 ÷ 0.77) of the total circle area F _pln. bounded by the radius of the inner contour of the outer ring of the BHA in the plane of the inlet opening.

The technical result provided by the above set of features consists in developing a method for fine-tuning an experimental turbojet engine made with improved performance characteristics, namely, thrust, as well as with increased engine reliability during operation. Improving the reliability of the test results carried out at the stage of finalizing the experimental turbojet engines is achieved due to the alternation of modes developed in the invention when performing test phases that are longer than the programmed flight time. In this case, typical flight cycles are preliminarily formed, on the basis of which the damage to the most loaded parts is determined according to the program, and on the basis of this, the required number of loading cycles is determined during the test. The full scope of the tests is formed, including the quick change of cycles in the full register from the quick exit to the maximum or full forced mode to the complete stop of the engine and then a representative long-term operation cycle is formed with multiple alternating modes in the entire operating spectrum with a different range of modes. This makes it possible to increase the correctness and expand the representativeness of the assessment of the resource and reliability of the engine at the stages of creation and refinement, and as a result of further serial production and flight operation of the turbojet engine and provides increased engine life under conditions typical of the subsequent real multi-mode operation of the turbojet engine in flight conditions on highly maneuverable aircraft.

The invention is illustrated by drawings, where:

figure 1 shows a turbojet engine, a longitudinal section;

figure 2 - input guide apparatus KND, top view.

In the method of refining a turbojet engine, a prototype engine made by double-circuit, twin-shaft is refined. The engine refinement is carried out in stages, for which they develop a program and algorithms for the final testing of an experimental turbojet engine. At each stage, a turbojet engine is tested for compliance with the specified parameters with a statistically representative amount, mainly from one to five engine instances, and a condition is examined of each of the experimental engine instances tested from the said number. To analyze and evaluate the condition of the turbojet engine, if necessary, disassemble with subsequent possible refinement and / or replacement of parts of any of the modules and / or units of the experimental engine. Inspect and, if necessary, replace any module damaged in the tests or inadequate with the required parameters, if modified.

A turbojet engine contains at least eight modules - from a low-pressure compressor 1 to an all-mode rotary jet nozzle. KND includes an input guide apparatus 2, as well as a rotor with a shaft 3, preferably containing no more than four impellers 4 with a system of blades 5. VNA 2 contains power radial racks 6, consisting of a fixed hollow and controllable movable elements. Radial racks 6 are evenly spaced in the plane of the input section with an angular frequency of placement of racks in the range (3.0 ÷ 4.0) units / rad.

The gas generator includes assemblies, namely an intermediate housing 7, a high pressure compressor 8, a main combustion chamber 9 and a high pressure turbine 9. Behind the gas generator, a low pressure turbine 11, a mixer 12, a frontal device 13, an afterburner 14 of the combustion and an all-mode rotary jet nozzle are sequentially located and coaxially mounted. The specified nozzle includes a rotary device 15, preferably detachably attached by a fixed element to the afterburner 14 of the combustion, and an adjustable jet nozzle 16, similarly attached to the movable element of the rotary device 15 with the possibility of making turns to change the direction of the thrust vector.

An air-air heat exchanger module 17 is installed above the main combustion chamber 9 in the external circuit of the turbojet engine, if necessary, inspecting any of at least sixty tubular block modules of the latter. In addition, they examine and produce the necessary refinement of the drive box of the motor units (not shown in the drawings) and integrating these modules into electrical, pneumatic, hydraulic - fuel and oil systems, including, if necessary, replacing sensors, command blocks, actuators and cables of the diagnostic systems and automatic engine control.

The experimental turbojet engine is refined, the axis of rotation of the rotary device 15 of the jet nozzle of which is made rotated relative to the horizontal axis by an angle of at least 30 °, preferably (32 ÷ 34) ° clockwise (view in the direction of flight) for the right engine and not at an angle less than 30 °, preferably (32 ÷ 34) ° counterclockwise (view in the direction of flight) for the left engine.

At the fine-tuning stage, at least one, preferably, the aforementioned representative number of copies of the experimental turbojet engine is subjected to a multi-cycle test. The multi-cycle test program includes the alternation of modes during the execution of the test stages with a turbojet operation duration exceeding the programmed flight time. First, typical flight cycles are formed and damage to the most loaded parts is determined. 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 turbojet engine, in aggregate, exceeding flight time by 5-6 times. A different range of changes in the operating modes of the turbojet engines is realized by changing the level of the gas differential in specific test modes from the initial to the maximum - maximum or full forced mode of the turbojet engine 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.

After that, the subsequent stages of tests and refinement of the turbojet engine are performed in the quantity necessary and sufficient to bring the engine into a condition suitable for transmission to bearer or state tests.

As part of communication systems, the air system is refined, highlighting the subsystems for cooling the overheated units, the anti-icing heating of the VNA engine and the pressurization subsystem for the bearings of the compressor and turbine rotors.

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 turbojet engines.

The experimental engine is refined, BHA 2 KND 1 of which preferably contains twenty-three radial struts 6 connecting the outer and inner rings 18 and 19, respectively, of the BHA 2 with the possibility of transferring loads from the outer casing 20 of the engine to the front support. At least a portion of the uprights 6 is aligned with the channels of the oil system located in the stationary elements of the uprights, with the possibility of supplying and discharging oil, as well as venting the oil and pre-oil cavities of the front support of the low pressure rotor.

The experimental turbojet engine is subjected to refinement, the frontal projection area of the entrance aperture is F _{in. etc.} VNA 2 KND 1 which geometrically defines the cross section of the inlet mouth of the air intake channel 21, bounded at a larger radius by the inner contour of the outer ring 18 of BHA 2, and at a smaller radius by the inner contour of the inner ring 19 of VNA, which is larger than the total aerodynamic shading area F _ct , created by the frontal projection of the Coca 22 and radial racks 6, (2.54 ÷ 2.72) times and is (0.67 ÷ 0.77) of the total circle area F _pln. bounded by the radius of the inner contour of the outer ring 18 VNA in the plane of the inlet opening.

An example of the implementation of testing an experimental turbojet engine according to a multi-cycle program.

A turbojet engine with a design resource of 500 hours of total running time is tested, until the first overhaul. In the indicated resource, the operating time is set to 20 hours at maximum mode, of which 5 hours at full forced mode. Typical flight cycles (TFCs) are formed and a predetermined engine operating time of 1 h is set, which is equivalent to the flight time of an aircraft (LA) according to the adopted TOC. Based on the fuel processing center, the damage to the most loaded parts is determined by calculation. On the basis of this, the required equivalent damage number of cycles during the tests is determined. In this embodiment, the following set of load test cycles is taken - performing 700 (400 + 300) starts with reaching the maximum and forced modes, respectively, as well as 400 pick-ups from the “low gas” (MG) mode to the maximum (Max.) And 300 from the mode 0.8 Max, before the forced (For) mode.

Set the safety factor for the required number of test load cycles and running hours K = 1.2.

Form the full scope of life tests and develop a test program:

1. The total operating time during the life tests is 500 · 1.2 = 600 hours, of which the maximum operating time is (20-5) · 1.2 = 18 hours, and in the forced mode 5 · 1.2 = 6 hours .

2. Take the duration of the test phase 5 hours and determine the number of five-hour steps 600: 5 = 120.

3. Set the number of starts taking into account the safety factor of 700 · 1.2 = 840, as well as from MG to Max 400 · 1.2 = 480 and from 0.8 Max to Fore 300 · 1.2 = 360.

4. Each five-hour stage includes 840: 120 = 7 pick-ups from the MG mode to Max 480: 120 = 4 and pick-ups from the 0.8 Max mode to Fore 360: 120 = 3, as well as the operating time at maximum and forced modes 18 · 60: 120 = 9 min, 360: 120 = 3 min.

5. Set the sequence of test cycles - quick exit to maximum or full forced mode, quick reset to MG mode and stop. Then, a long-term operation cycle is provided with multiple alternation of load cycles with a range of regime change ranges from MG to Max and 0.8 Max to For within the range of the test stages established above.

Perform tests of turbofan engines according to the specified program. Then the engine is faulted and the test results are analyzed, according to which a decision is made to recognize the engine as tested.

Claims (6)

1. A method of refining an experimental turbojet engine, characterized in that the experimental engine is refined, made by double-circuit, twin-shaft, while refining the engine is carried out in stages, for which a program and algorithms for refining tests of an experimental turbojet engine are developed; at each stage, a statistically representative amount of one to five instances is tested for compliance with the specified parameters and a condition is examined for each of the tested instances of the experimental engine; for analysis and assessment of the condition, disassembly is carried out, followed by possible refinement and / or replacement of parts of any of the modules and / or components of the experimental engine, examined and replaced with the modified one of any module damaged in the tests or not meeting the required parameters, including low pressure compressor (LPC) with an input guide vane (VNA) containing radial power racks consisting of a stationary hollow and controllable movable elements and uniformly spaced in the plane of the input section with an angular cha the rack placement frequency in the range (3.0 ÷ 4.0) units / rad, as well as a rotor with a shaft containing not more than four impellers with a blade system; a gas generator including assembly units — an intermediate casing, a high pressure compressor, a main combustion chamber and a high pressure turbine; sequentially located behind the gas generator, coaxially mounted low-pressure turbine; mixer; front-end device, afterburning combustion chamber and an all-mode rotary jet nozzle, including a rotary device detachably attached by a fixed element to the afterburner of combustion, and an adjustable jet nozzle, similarly attached to a movable element of the rotary device with the possibility of making turns to change the direction of the thrust vector; as well as an air-air heat exchanger module installed above the main combustion chamber in the external circuit, inspecting any of at least sixty tubular block modules of the latter, in addition, they inspect and produce the necessary refinement of the motor unit drive box (KDA) and the electrical modules uniting these modules, pneumatic, hydraulic - fuel and oil systems, including replacement of sensors, command blocks, actuators and cables of diagnostic and automatic engine control systems ; wherein the experimental turbojet engine is refined, the axis of rotation of the indicated rotary device of the jet nozzle of which is made rotated relative to the horizontal axis by an angle of at least 30 ° clockwise for the right engine and an angle of at least 30 °, counterclockwise for the left engine; at the same time, at the fine-tuning stage, not less than one or the aforementioned representative number of copies of the experimental turbojet engine is subjected to a multi-cycle test; the specified test program includes the alternation of modes when performing test phases with a turbofan engine operating longer than the programmed flight time, for which typical flight cycles are first formed and the damageability of the most loaded parts is determined, based on this, the required number of loading cycles is determined during the test, and then the full cycle is formed and produced scope of tests, including the execution of a sequence of test cycles - quick exit to maximum or full forced mode, fast resetting to the “low gas” mode, stopping and a long operation cycle with multiple alternating modes in the entire operating spectrum with a different range of variation in the operating modes of a turbojet engine, which in aggregate exceeds the flight time by 5-6 times; at the same time, a different range of changes in the operating modes of the turbojet engine is realized by changing the level of the gas differential in specific test modes from the initial to the maximum - maximum or full forced mode of the turbojet engine by transferring the initial reference point when the corresponding mode is executed, taking the latter in one of the modes in position corresponding to the “small gas” level, and in other modes - in intermediate or final positions corresponding to different percentages or the full value of the maxim gas level full or forced mode, moreover, a quick exit to the maximum or forced modes on part of the test cycle is carried out at the rate of acceleration followed by reset, after which the subsequent stages of testing and fine-tuning the turbojet engine are carried out in an amount necessary and sufficient to bring the engine into a condition suitable for transmission bearer or state trials. 2. The refinement method of the experimental turbojet engine according to claim 1, characterized in that, as part of the communication systems, the air system is refined, highlighting the cooling subsystems of the overheated units, the anti-icing heating of the VNA engine and the boost subsystem of the bearings of the compressor and turbine rotors. 3. The refinement method of the experimental turbojet engine according to claim 1, characterized in that part of the test cycles is carried out without heating in the "small gas" mode after starting. 4. The refinement method of an experimental turbojet engine according to claim 1, characterized in that the test cycle is formed on the basis of flight cycles for military and educational use of turbofan engines. 5. The refinement method of an experimental turbojet engine according to claim 1, characterized in that the experimental engine is subjected to refinement, VNA KND of which contains twenty-three radial struts connecting the outer and inner rings of VNA with the possibility of transferring loads from the external engine casing to the front support, and racks 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 low pressure rotor. 6. The refinement method of an experimental turbojet engine according to claim 5, characterized in that the experimental turbojet engine is subjected to refinement, the frontal projection area of the entrance aperture is F _input. VNA KND which geometrically determines the cross section of the inlet mouth of the air intake channel, bounded at a larger radius by the inner contour of the outer ring of the VHA, and at a smaller radius by the inner contour of the inner ring of the VHA, is larger than the total area of aerodynamic shading F _c created by the frontal projection of the coke and radial struts, in (2.54 ÷ 2.72) times and is (0.67 ÷ 0.77) of the total area of the circle F _pln. bounded by the radius of the inner contour of the outer ring of the BHA in the plane of the inlet opening.

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