RU2730558C1 - Double-flow turbine jet engine - Google Patents

Abstract

FIELD: machine building.SUBSTANCE: double-flow turbojet engine comprises fan 1, high pressure compressor 2, combustion chamber 3, high pressure turbine 4 and low pressure turbine 5. In order to solve the task of increasing the economy of a double-flow turbojet engine due to reduction of hydraulic losses in the annular channel of its outer contour, external housing 9 of the engine consists of external 13 and internal 14 coaxial annular walls, between which there are helical ribs 15 in number of not less than three pieces, which divide annular cavity between walls 13 and 14 on screw channels 16 for passage of air intended for cooling of high pressure turbine. Inlet of screw channels 16 is connected to holes 17 made in housing 18 of high pressure compressor 2, branch pipes 19 with openings 20. Outlet of screw channels 16 by branch pipes 21 with openings 22 is connected to holes 23 made in housing 24 of low pressure turbine 5, which are interconnected with holes 27 for passage of cooled air, made in housing of high pressure turbine.EFFECT: broader functional capabilities.1 cl, 3 dwg

Description

The invention relates to by-pass turbojet engines for aircraft use.

Known two-circuit turbojet engine containing a fan, an outer engine casing, a high-pressure compressor, a combustion chamber, high and low pressure turbines with an afterburner in the internal circuit for heating the exhaust gases of the turbine, as well as with an afterburner burner in the external circuit channel. The air taken from the high-pressure compressor to cool the turbine is pre-cooled in air-to-air heat exchangers installed in the external circuit duct, heating the air directed to the afterburner burner installed in the external circuit (US Patent 3528250 F02C 7/18, F02K 3 / 04, 3/10, published September 15, 1970).

The main disadvantage of this two-circuit turbojet engine is the increased level of hydraulic losses in the channel of the outer circuit due to its blockage by air-to-air heat exchangers placed in it, leading to a decrease in its efficiency.

The closest to the proposed technical solution is a two-circuit turbojet engine with a sectional air-to-air heat exchanger in the outer circuit channel, located in the recess of the gas generator fairing with an inclination towards the air flow (Patent RU 2488710 F02K 3/08, published July 27, 2013).

This engine also has reduced efficiency due to increased hydraulic losses in its external circuit due to blockage of its flow section with air-air heat exchanger sections, which is a disadvantage.

The technical problem solved by the invention is to increase the efficiency of a by-pass turbojet engine by reducing hydraulic losses in the annular channel of its outer contour.

The essence of the invention lies in the fact that in a by-pass turbojet engine containing a fan, an outer casing of the engine, a high-pressure compressor, a combustion chamber, a turbine for driving a fan and a high-pressure compressor, the outer casing of the engine is made in the form of two coaxial annular walls, between which at least than three ribs that form helical channels for the passage of air intended for cooling the turbine, while the inlet of the helical channels is connected to the holes made in the housing of the high-pressure compressor, and their outlet to the holes made in the housing of the low-pressure turbine communicating with the holes for chilled air passage made in the high pressure turbine housing

The design of the outer casing of the engine in the form of two coaxial annular walls, between which at least three ribs are located, forming helical channels for the passage of air intended for cooling the turbine, makes it possible to use for heat exchange the surfaces of the annular walls in contact with air flows in the purge channel of the engine nacelle of the aircraft and in the outer circuit of the engine.

The connection of the inlet of the screw channels with the holes made in the housing of the high-pressure compressor, and their outlet with the holes made in the housing of the low-pressure turbine communicating with the holes for the passage of cooled air made in the housing of the high-pressure turbine allows, in combination with the screw channels, to move air flows with multiple cross-flow, in which the air intended for cooling the turbine moves along the helical channels in the outer casing of the engine, and the air flows in the purge duct of the engine nacelle and in the outer circuit of the engine along its axis, providing a high efficiency of pre-cooling of the air intended to cool the turbine, while reducing hydraulic losses in the external circuit of the engine, contributing to an increase in its efficiency.

The invention is illustrated in the following drawings.

FIG. 1 shows a longitudinal section of a by-pass turbojet engine, FIG. 2 - air supply to the screw channels of the outer casing of the engine (view A in Fig. 1); in fig. 3 - air supply to the high-pressure turbine cooling system (view B in Fig. 1).

The two-circuit turbojet engine contains a fan 1, a high-pressure compressor 2, a combustion chamber 3, a high-pressure turbine 4 and a low-pressure turbine 5. The low-pressure turbine 5 drives fan 1, and the high-pressure turbine 4 drives the high-pressure compressor 2. Between the fan 1 and the high-pressure compressor 2 is located an intermediate casing 6, dividing the air flow behind the fan 1 into the outer 7 and inner 8 circuits. The outer casing of the engine 9 is attached to the intermediate casing 6. The engine is installed in the nacelle of the aircraft 10 with a purge channel 11. A cavity 12 is located behind the high-pressure compressor 2 in front of the combustion chamber 3, from which air is taken to cool the high-pressure turbine 4. The outer casing of the engine 9 consists of an outer 13 and an inner 14 coaxial annular walls, between which there are at least three helical ribs 15, which divide the annular cavity between the walls 13 and 14 into helical channels 16 for the passage of air intended for cooling the high-pressure turbine. The inlet of the screw channels 16 is connected to the holes 17 made in the housing 18 of the high pressure compressor 2, by the branch pipes 19 with windows 20. The outlet of the screw channels 16 by the branch pipes 21 with the windows 22 is connected to the holes 23 made in the housing 24 of the low pressure turbine 5. In the housing 25 of the high pressure turbine 4, nozzle blades 26 are fixed and holes 27 are made, communicating with the holes 23 in the housing of the low pressure turbine 5, for the passage of cooling air into the cavity 28 in the inner housing 29 of the nozzle apparatus of the high pressure turbine 4 with nozzle holes 30. Rotor of the high pressure turbine 4 includes a turbine disk 31, a cover disk 32 and rotor blades 33. In the cover disk 32 and in the turbine disk 31 there are holes 34 and 35, respectively, for supplying air to the rotor blades 33.

When a two-circuit turbojet engine is operating, atmospheric air enters the inlet to its fan 1 and to the purge channel 11 of the nacelle of the aircraft 10. The air flow with increased pressure behind the fan 1 in the intermediate casing 6 is divided into outer 7 and inner 8 circuits. The air of the internal circuit enters the inlet to the high pressure compressor 2, and the air of the external circuit 7 enters the channel formed by the outer casing of the engine 9 and the casing 18 of the high pressure compressor 2. High pressure air from the high pressure compressor 2 enters the combustion chamber 3 and further , in the form of products of combustion of hydrocarbon fuel, in the turbines of high 4 and low 5 pressure. Air is taken from the cavity 12 behind the high-pressure compressor 2 in front of the combustion chamber 3 for cooling the high-pressure turbine 4. The cooling air enters through holes 17 in the housing 18 of the high-pressure compressor 2, pipes 19 with windows 20 into the screw channels 16 of the outer casing of the engine 9, formed by its outer 13 and inner 14 annular walls and ribs 15 between them. Passing through the helical channels 16, the cooling air gives up a part of its thermal energy through the wall 13 to the air flow in the purge channel 11, and through the wall 14 to the air flow in the external circuit 7 of the engine. As a result, the temperature of the cooling air decreases. The cooled air leaves the channels 16 through the nozzles 21 with windows 22 to the openings 23 made in the housing 24 of the low pressure turbine 5, and then through the communicating openings 27 made in the housing 25 of the high pressure turbine 4, it passes through the cavities of the nozzle blades 26 into cavity 28 in the inner housing 29 of the nozzle apparatus of the high-pressure turbine 4. Through the nozzle holes 30 in the inner housing 29, holes 34 and 35, respectively, in the cover disk 32 and disk 31 of the high-pressure turbine 4, cooled air enters the rotor blades 33 of the high-pressure turbine 4 ...

Thus, the implemented pattern of air flows with multiple cross-flow ensures high efficiency of pre-cooling of the air intended for cooling the turbine, and minimizing the blockage of the external circuit reduces hydraulic losses in it, which contributes to an increase in engine efficiency.

Claims (1)

A two-circuit turbojet engine containing a fan, an outer engine casing, a high-pressure compressor, a combustion chamber, a fan drive turbine and a high-pressure compressor, characterized in that the outer engine casing is made in the form of two coaxial annular walls, between which at least three ribs are located, forming screw channels for the passage of air intended for cooling the turbine, while the inlet of the screw channels is connected to the holes made in the housing of the high-pressure compressor, and their outlet to the holes made in the housing of the low-pressure turbine communicating with the holes for the passage of cooled air, made in the high pressure turbine housing.

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