RU2389886C1 - Combined nuclear aircraft engine - Google Patents

Abstract

FIELD: engines and pumps.

SUBSTANCE: combined nuclear aircraft engine includes two-spool gas turbine engine with internal and external shafts and two spools of compressor, and combustion chamber to which there connected is fuel pipeline from fuel pump, turbine and jet nozzle. After turbine, on internal engine shaft there installed is Stirling engine which includes at least one operating cylinder installed downstream the turbine, and at least one expansion cylinder installed downstream operating cylinder. Before operating cylinder there installed is heat exchanger connected via recirculation pipelines to nuclear reactor. Each expansion cylinder has a casing forming together with that cylinder a cooling cavity. Cooling cavity inlet is connected to outlet of air supply connection pipe the inlet whereof is connected via flow control to compressor cavity. Cooling cavity outlet is connected to cavity inside jet nozzle. All the expansion cylinders are installed partially or completely inside jet nozzle shield.

EFFECT: increasing efficiency of aircraft engine at decrease of its weight, cost and improvement of reliability.

2 cl, 3 dwg

Description

The invention relates to aircraft engine manufacturing.

Known aircraft combined engine according to the application of the Russian Federation for invention No. 2002115896, containing a gas turbine engine and a rocket engine.

The disadvantage is the very high fuel consumption consumed by the rocket engine.

Known aviation gas turbine engine according to the patent of Russian Federation No. 2211935, a prototype containing a compressor, a combustion chamber, a turbine and a jet nozzle.

Disadvantages - low efficiency and, as a result, high specific fuel consumption.

The task of creating the invention, a significant increase in engine efficiency.

The solution of these problems was achieved in a combined nuclear aircraft engine containing a two-stage gas turbine engine with internal and external shafts and two compressor stages, a combustion chamber, to which the fuel pipe from the fuel pump, a turbine and a jet nozzle are connected, in that behind the turbine on the internal engine shaft a Stirling engine is installed, which contains at least one working cylinder mounted downstream of the turbine, and at least one expansion cylinder is installed downstream of the working cylinder, and a heat exchanger is installed in front of the working cylinder, connected by recirculation pipes to the nuclear reactor, each expansion cylinder has a casing that forms a cooling cavity with this cylinder, the entrance to the cooling cavity is connected to the outlet of the air supply pipe, the input of which is connected through a regulator flow with the compressor cavity, the outlet from the cooling cavity is connected to the cavity inside the jet nozzle. All expansion cylinders are partially or completely installed inside the radome of the jet nozzle.

The proposed technical solution has novelty, inventive step and industrial applicability, as evidenced by patent research. To implement the invention, it is sufficient to use the known components and parts previously developed and implemented in the design of gas turbine engines and in mechanical engineering.

The invention is illustrated in figure 1 ... 3, where:

figure 1 shows a diagram of an aircraft engine,

figure 2 shows a diagram of a Stirling engine,

figure 3 shows a section aa.

The proposed technical solution (figure 1) contains a gas turbine engine GTE 1, which is made of a two-shaft and contains an internal shaft 2 and an external shaft 3, a compressor 4, which in turn consists of the first and second stages of the compressor, respectively 5 and 6, then the combustion chamber 7 , a turbine 8, which in turn contains a nozzle apparatus 9 and an impeller 10. The shafts 2 and 3 are mounted on supports 11. The gas turbine engine 1 comprises a fuel supply system with a fuel pump 12 and a fuel pump drive 13, a fuel pipe 14, annular to the collector 15, to which the fuel pipe 14 is connected, and then the combustion chamber 4. Next, a jet nozzle 15 with a conical shape fairing 16 inside it, fixed by ribs 17, is installed downstream.

A distinctive feature of the power plant is the presence of the Stirling engine 18 behind the turbine 8, i.e. behind her impeller 10.

The Stirling engine 18 consists of two parts: a group of working cylinders 19 and a group of expansion cylinders 20, which are connected by pipelines 21. It is preferable to install the group of expansion cylinders 20 outside the gas turbine engine path, for example, in whole or in part in the fairing 16.

Figure 2 and 3 shows a diagram of one embodiment of a Stirling engine 18, which contains a group of working cylinders 19 having fins 22 with a working piston 23 installed inside each of them in the cavity "B", which is connected to the engine shaft 2 by a connecting rod 24, and a group of expansion cylinders 20 with a displacement piston 25 installed inside each of them in the cavity “B”. Each expansion cylinder 20 is equipped externally with a casing 26 forming a cavity “G” for cooling the expansion cylinder 20. The displacement piston 25 is connected Tun 27 with a shaft 2 of the engine. The pipe 21 connects the cavity "B" and "C" for the flow of the working fluid from the working cylinder 19 into the expansion cylinder 20. To the cavity "G" the outputs of the air inlet pipes 28 are connected, and the exhaust pipes 29 connect the cavity "G" with the internal cavity "D" jet nozzle 15 (figure 1). The inputs of the intake pipes 28 through a flow regulator 40 having a drive 30 are connected to the cavity of the compressor 4.

A heat exchanger 31 is installed in front of the working cylinder 19 (working cylinders 19), which is connected to a nuclear reactor 35 by recirculation pipes 32 and 33, in one of which a recirculation pump 34 is installed.

The aircraft engine is equipped with a control unit 36 and rotational speed sensors of the internal and external shafts 37 and 38, respectively. Speed sensors 37 and 38 and actuators 13 and 30 are connected to the control unit 36 by electrical connections 39.

When working with a starter (not shown in FIGS. 1 ... 3), a gas turbine engine 1 is started, while the drive of the pump 13 is turned on, the fuel pump 12 delivers fuel through the fuel pipe 14 to the annular manifold 15 and then to the combustion chamber 7.

The fuel is ignited using an electric igniter (not shown in FIGS. 1 ... 3). The exhaust gases pass through the turbine 8. The impeller of the turbine 9 with the external shaft 3 of the gas turbine engine 1 is untwisted, i.e. TBG 1 is starting.

The Stirling engine starts much later due to its inertia. The connecting rods 24 and 27 and the pistons 23 and 25 of the Stirling engine are driven by the internal shaft 2 of the gas turbine engine 1 from the compressor of the first stage 4, which is unwound in the autorotation mode by the air passing through it. The mechanism for converting rotational motion into reciprocating (this mechanism is not shown in detail in FIGS. 1 ... 3, but it can be made in the form of a crankshaft with connecting rods) converts the rotational motion of the inner shaft 2 into the reciprocating motion of the pistons 23 and 26 of the Stirling engine 18. The exhaust gases are heated through the fins 22 of the working fluid inside the working cylinders 19. For the Stirling engine to work, it is enough to have a temperature difference on the two groups of cylinders 19 and 20. Initially, the Stirling engine runs it doesn’t give out power, but, on the contrary, consumes it. After about 5 ... 10 min, as the working fluid warms up inside the working cylinders 19 of the Stirling engine, it reaches the calculated operating mode. The slow exit of the Stirling engine to the calculated operating mode is one of its drawbacks, but high efficiency, reliability and good environmental properties, combined with a gas turbine engine with good starting characteristics, makes the proposed engine extremely interesting in all respects at the same time, because will allow to partially utilize heat in the jet nozzle and use only one step instead of 4-5 turbine stages.

After entering the regime of the gas turbine part of the aircraft engine, a nuclear reactor 35 is started, the coolant pump 34 is turned on and the coolant is fed through a recirculation pipe 33 to a heat exchanger 31, where it heats the combustion products at the inlet of the Stirling engine 18. The engine power increases by about 2 times, it also increases profitability due to the increase in temperature at which heat is supplied in the cycle.

The second feature of a combined atomic aircraft engine is the presence of its regulation system using a flow regulator. The design of such a system caused difficulties, as there is no system for supplying fuel to the Stirling engine, and the regulation of the flow of combustion products in front of the working cylinders 19 is difficult and leads to a deterioration in the efficiency of the engine as a whole due to clutter of its gas path. The regulation of the operating mode of the Stirling engine is necessary in order to ensure its operation together with the first stage of the compressor in the optimal efficiency mode (in design mode). This is necessary because, unlike stationary gas turbine units, aircraft engines are operated in a wide range of ambient temperatures (from +40 to -76 ° C) and at pressures from 1 kgf / cm ² almost to vacuum at a flight height of 10,000 m to 25,000 m

The engine can operate in three modes:

- the nuclear reactor is not working, the fuel system is working,

- only a nuclear reactor works,

- a nuclear reactor and fuel system are operating at the same time.

As a result of the use of heat recovery from exhaust gases in the Stirling engine, the efficiency of an aircraft engine increases by about 10 ... 17%.

The application of the invention allowed:

1. Significantly increase the power and efficiency of an aircraft engine by using, in addition to the gas turbine engine, a Stirling engine and a nuclear reactor to obtain energy on the shaft.

2. To coordinate the work of the gas turbine engine and the Stirling engine, which have different inertia, due to the use of a two-stage two-shaft gas turbine engine.

3. Provide regulation of the operation of the Stirling engine.

4. To increase the reliability of the engine due to its operation in three modes depending on the use of a nuclear reactor and fuel system.

5. Facilitate the launch of the combined aircraft engine through the use of a two-shaft scheme and start only the second stage.

6. To reduce the number of stages of the turbine due to the fact that their function is assumed mainly by the Stirling engine.

7. To reduce the emission of toxic substances into the atmosphere due to the fact that the Stirling engine has significantly better environmental performance compared to other types of engines.

8. To reduce the cost of the aircraft engine by reducing the number of expensive stages of the turbine, the blades and disks of which are made of heat-resistant alloys and simplify the cooling scheme of the turbine.

9. Reduce the weight of the aircraft engine, which is especially important in aviation.

10. Improve the reliability of the aircraft engine by abandoning several stages of the turbine, the blades of which are the most loaded parts of the engine, limiting its life and primarily affecting the reliability of the engine, aircraft and the safety of air transportation.

Claims (2)

1. Combined nuclear aircraft engine containing a two-stage gas turbine engine with internal and external shafts and two compressor stages, a combustion chamber to which the fuel pipe is connected from the fuel pump, a turbine and a jet nozzle, characterized in that the engine is installed behind the turbine on the internal shaft of the engine Stirling, which contains at least one working cylinder mounted downstream of the turbine, and at least one expansion cylinder installed behind the working cylinder m downstream, while in front of the working cylinder there is a heat exchanger connected by recirculation pipelines to a nuclear reactor, each expansion cylinder has a casing that forms a cooling cavity with this cylinder, the entrance to the cooling cavity is connected to the outlet of the air supply pipe, the input of which is connected through the flow regulator to the cavity compressor, the outlet from the cooling cavity is connected to the cavity inside the jet nozzle. 2. The combined atomic aircraft engine according to claim 1, characterized in that all the expansion cylinders are partially or completely installed inside the radome of the jet nozzle.

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