RU2319024C1 - Gas turbine locomotive - Google Patents

Abstract

FIELD: mechanical engineering; gas-turbine locomotives.

SUBSTANCE: power plant of gas-turbine locomotive contains gas-turbine engine at output of which free turbine is mounted and at its output, exhaust device is installed. Gas-turbine engine and free turbine are installed on frame in container provided with cooling system combined with system to adjust radial clearances in gas-turbine engine and/or free turbine, and with fire-fighting system.

EFFECT: improved starting, increased economy of gas turbine locomotive.

3 cl, 14 dwg

Description

The invention relates to railway transport and can be used as a power plant for a gas turbine locomotive, i.e., a locomotive based on a gas turbine engine.

Known power plant according to the patent of the Russian Federation on the invention No. 2137617, this installation has a liquid cooling system and a fan to create a flow of cooling air.

A known power plant according to the patent of the Russian Federation No. 212418, which contains a gas turbine engine, a gas path connecting this gas turbine engine with a power turbine, and a bypass channel that connects the gas path between the turbines and in front of the free turbine.

The disadvantage of this power plant is the poor performance of its launch, specifically the long launch time. This is due to the fact that the gasdynamic resistance of a free turbine is significant and the starter power is not enough to simultaneously spin up several gas turbine engines and a free turbine, from which power is taken to the transmission.

Known gas turbine power plant according to the patent of the Russian Federation for the invention No. 2189477, a prototype that contains modules of a gas generator, gas turbine drive and exhaust, interconnected.

Disadvantages: low safety level due to the absence of a fire extinguishing system, measures to reduce noise, vibration, high surface temperature of the installation, poor ergonomic properties, inconvenience in operation, the possibility of damage during transportation of the product to the place of operation.

The objectives of the invention are to ensure the safety of maintenance of the power plant, reducing noise and vibration.

The solution to these problems was achieved due to the fact that the power plant of a gas turbine locomotive containing a gas turbine engine, at the outlet of which a free turbine is installed, at the outlet of which an exhaust device is installed, characterized in that the gas turbine engine and a free turbine are mounted on a frame in a container having cooling system combined with a radial clearance control system in a gas turbine engine and / or in a free turbine and with a fire extinguishing system. The container is made of two parts and has a longitudinal connector and hatches for inspection and replacement of units, and the frame is attached to the bottom of the container. The power plant contains an oil cooling system with an oil-air heat exchanger. The generator may be located at the entrance to the gas turbine engine or at the outlet of the power turbine. The container is made of two parts: the upper and lower, the front of the frame is rigidly attached to the lower part of the container, and the rear to is attached with the possibility of axial movement. The container is lined with heat and sound insulating material inside and / or outside. The power plant is made in a modular design

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 well-known components and parts previously developed and implemented in mechanical engineering.

The invention is illustrated in figure 1 ... 14, where:

figure 1 shows the first diagram of the power plant of a gas turbine locomotive without bypass,

figure 2 diagram of the regulation of radial clearances,

figure 3 shows a diagram of the compressor

figure 4 ... 6 shows a diagram of oil cooling,

Fig.7 shows a turbine and a free turbine with the location of the generator at the outlet of the free turbine,

on Fig shows a diagram of a turbine and a free turbine with the location of the generator at the entrance to the gas turbine engine,

figure 9 shows a diagram of the compressor with the location of the generator at the entrance to the gas turbine engine,

figure 10 and 11 shows the design of the container,

on Fig shows a diagram of the power plant of a gas turbine with bypass due to the high pressure turbine,

Fig.13 shows a diagram of the power plant of a gas turbo locomotive with bypass due to the high pressure turbine and due to the medium pressure turbine,

on Fig shows a diagram of the power plant of a gas turbine with bypass due to high pressure turbines, medium pressure and low pressure,

The proposed technical solution (Fig. 1) comprises a gas turbine engine GTE 1 and a free turbine 2 installed at the exit of the gas turbine engine 1. A cavity at the exit of the free turbine 2 is formed by the body of the free turbine 3. An exhaust device 4 is installed at the exit of the free turbine.

The gas turbine engine 1 comprises an input device 5, a compressor 6, a combustion chamber 7 having a fuel supply system 8 and a fuel pump 9, and a turbine 10.

An electric generator 11 is connected to a free turbine 2, which, through electrical connections 12 through a switch 13, is connected to drive electric motors 14, which, in turn, are connected to drive wheel pairs 15. With one of the rotors of the turbine engine 1, preferably with the rotor of the third stage of the turbine engine 1 , through the shaft 16 is connected an auxiliary diesel engine 17, designed for maneuvering a gas turbine locomotive and for starting a gas turbine engine 1. An auxiliary electric generator 18, designed for maneuvering gas, is connected to the auxiliary diesel engine 17 rbovoza. Couplings auxiliary diesel 17 in figure 1 is not shown. By electrical connections 12, the auxiliary generator 18 through the switch 13 has the ability to connect with electric motors 14.

Compressor 6 (Fig. 1) consists of a cascade of a low-pressure compressor 19, a cascade of a medium-pressure compressor 2 and a cascade of a high-pressure compressor 21. The turbine 10 consists of a high-pressure turbine 22, a medium-pressure turbine 23, and a low-pressure turbine 24. A free turbine 2 consists of from an adjustable guide apparatus 25 with a control drive 26 and an impeller of a free turbine 27.

The power plant control circuit provides at least one speed sensor 28 and a control unit 29 connected by electrical connections.

GTE 1 has an outer casing 30, the temperature of which can reach 100 ... 130 ° C, which is unsafe during maintenance. In addition, on the surface of the outer casing 10 there are control and regulation units, access to which is absolutely undesirable. Also, when transporting the power plant from the manufacturer to the customer, these units can be damaged. To eliminate these drawbacks powerplant installed in the container 31. For maintenance units are provided closing the hatches 32. The CCD 1 is mounted in a container 31 on the frame 33. The front portion 33 of the frame ₁ is rigidly secured to the bottom of the container, and the rear portion 33 ₂ is fixed axially movements to compensate for thermal expansions.

A cooling system is provided for the outer casing 30 and the casing of the free turbine 4, combined with a radial clearance control system and with a fire extinguishing system (FIG. 2).

An original feature of the power plant is that it is equipped with a gas turbine engine cooling system 1 and a free turbine 2, combined with a radial clearance and fire extinguishing system. All these systems have an exit of cooling air and inert gas used to extinguish a fire source inside a container. This system contains a cooling air supply system 34, an air discharge system 35, and an air temperature sensor 36 connected by electrical connection to the control unit 29. (Fig. 2) . The cooling air supply system 34 comprises an annular manifold 37 with holes “B”. An air intake pipe 38 with an air flow regulator 39 is connected to the cavity behind the first stage of the compressor’s first stage, an outlet 40 is connected to the outlet, connecting this regulator to the annular collector 37. The annular collector has openings “B” around the entire circumference to ensure uniform cooling of the GTL case 1 and free turbine 2, for uniform regulation of the radial clearances in the turbine engine 1 and in the free turbine between the ends of the compressor blades and the turbine and the bodies of the turbine engine and the free turbine. A fire extinguishing system 41 is connected to the annular manifold 38, which is an inert gas supply pipe and a fire damper. (The fire damper is not shown in FIGS. 1 ... 14). The fire system also contains fire sensors inside the container (they are not shown in FIGS. 1 ... 14 either).

Combining the functions of three important systems can not only reduce the number of parts and assemblies, for example, use one ring collector instead of three, but also simplify the system and increase its reliability. This will also reduce the weight of the power plant and its cost in manufacturing. In addition, the management and maintenance of the power plant will be improved and simplified during both operation and repair. Regulation of radial clearances will increase the power plant efficiency by 2 ... 3% in all modes.

In addition, the use of an air flow regulator 39 will allow you to adjust the summer and winter modes of operation of the power plant, for example, when operating the power plant at negative temperatures, the flow rate of sampled air can be reduced several times, this will further increase the efficiency of the installation by 2.2 ... 2, 7% estimated. This is explained by the fact that the need for cooling the GTE case is practically eliminated, and less air is needed to reduce the radial clearance, and a decrease in air extraction due to intermediate compressor stages increases the consumption of combustion products through the turbine and free turbine and, as a result, the efficiency of the installation.

The inner or outer surfaces of the container must be covered with heat and sound insulating material, such as asbestos or mineral wool. Non-combustible materials should be used.

The application of these measures will allow:

- reduce noise,

- reduce the surface temperature of the container and reduce the flow of air taken to cool the gas turbine engine and a free turbine,

- ensure fire safety of the power plant.

In addition, the container protects the gas turbine locomotive powerplant from damage and atmospheric precipitation during its transportation from the manufacturer to the installation site on the locomotive for operation. The frame is fixed with its front to the bottom of the container rigidly, while turning or moving the front attachment point is unacceptable, because this will lead to a deviation of the exhaust device thrust vector, distortion of the gas turbine engine shafts and a free turbine, which will negatively affect the operation of the coupling. The rear part of the frame should be mounted with the possibility of axial movement to compensate for the thermal expansion of the parts of the gas turbine engine, primarily the case.

The compressor (figure 3) contains the guiding devices of the first stage of the compressor 42, the impellers of the first stage of the compressor 43 mounted on the disks of the compressor of the first stage 44 on the shaft of the first stage of the compressor 45. The second stage of the compressor contains the guiding devices of the second stage of the compressor 46, the impellers of the second stage compressor 47 mounted on the disks of the second stage of the compressor 48, which, in turn, are installed on the intermediate shafts 49. Next, guide vanes of the third stage of the compressor 50 are installed, then the impellers of the third stage of the compressor 51, mounted on the disks of the third stage of the compressor 52, installed, in turn, on the inner shaft 53. (figure 3).

The power plant is equipped with an oil cooling system on all supports (Figs. 4 ... 6) and contains an oil supply system 54 and an oil drainage system 55. In addition, the oil cooling system includes an air-oil heat exchanger 56 connected to an oil drainage system 55, an oil pump 57 , oil pump drive 58, oil temperature sensor 59, air supply system 60, fan 61 and collection pipe 62. The air supply system 60 can operate in two ways: from a high-pressure air pressure when moving a gas turbine and from a fan 61.

The oil cooling system can be equipped with an air damper 63 installed in front of the fan 61 (figure 5).

If liquefied natural gas LNG is used as fuel for gas turbine engine 1, then an air-fuel heat exchanger 64 installed in front of fan 61 can be used (Fig. 6).

The turbine engine of the turbine engine (Fig. 7) comprises a nozzle apparatus for a high-pressure turbine 65, an impeller of a first stage of a turbine 66 mounted on a disk of a turbine 67, a nozzle apparatus for a medium-pressure turbine 68, an impeller for a medium-pressure turbine 69 mounted on medium-pressure turbine disks 70, nozzle apparatus of the low pressure turbine 71, impeller (wheels) of the low pressure turbine 72 mounted on the disks of the low pressure turbine 73, rear support 74.

A free turbine 2 contains one or more impellers of a free turbine 74 with a disk (s) 27, which (which) are mounted on a shaft of a free turbine 76 connected to the shaft of an electric generator 77 (Fig. 9).

The container 31 (FIGS. 10 and 11) is preferably made of two parts: the upper 78 and the lower 79 with the joint "G".

The power plant may contain one of three bypass channels, or two of them, or all three in a common layout, i.e. There are seven possible options. The application further describes 4 options, the first of which (without bypass) is shown in figure 1.

The second option (Fig) contains a bypass channel 80, which connects the output of the medium pressure turbine with the output of the free turbine 2. This bypass channel contains a high pressure flow controller 81 with the drive 82.

The medium pressure bypass channel 83 (Fig. 13) connects the medium pressure turbine exit to the output of their free turbine 2. An average pressure regulator 84 with a drive 85 is installed in the line of this bypass channel.

The low pressure bypass channel 86 (Fig. 14) connects the output of the low pressure turbine to the output of the free turbine 2 and comprises a low pressure regulator 87 with a drive 88.

When starting the power plant, an electrical signal is supplied from the control system 29 to the auxiliary diesel engine 17, which performs the function of a starter (Fig. 1), and to the fuel pump 9. The auxiliary diesel engine 17 spins the high pressure rotor, i.e. the outer shaft 53 with the compressor of the second stage 6 and low pressure turbine 8. The power of the auxiliary diesel 17 is spent on the promotion of only one of the three rotors of the gas turbine engine 1, namely the high pressure rotor.

When the gas turbine engine GTE 1 is started, its speed is reached by the workers, which is controlled by the speed sensor 28, the control unit 29 sends a signal to the drives one or two or three drives 82, 85 and 88, the valves 81, 84 and 87 are closed. The rotors of medium and low pressure and the rotor of a free turbine 2 are untwisted.

As a result of this, GTE 1 starts much faster, because the power of the auxiliary diesel engine, which serves as a starter, is not spent on the promotion of medium and low pressure rotors of the turbine engine 1 and on the promotion of the rotor of a free turbine 2.

Temperature sensors 36 monitor the air temperature at the outlet of the cooling systems and regulate radial clearances and transmit this data to the control unit 29. When the outlet air temperature exceeds, for example, more than 95 ° C, the control unit 29 sends a signal to the actuator 40 to open the controller 39 . (figure 2). At temperatures below 80 ° C, a signal is sent to cover the regulator 39. This allows you to maintain a minimum radial clearance between the blades and stators of compressors, turbines and a free turbine. As a result, the efficiency of the power plant will increase by 2 ... 4% compared with the best world models of products of similar purpose, and fuel consumption will decrease accordingly.

At the same time, a gas turbine locomotive (locomotive) has the ability to use GTE 1 power in the range of 6 to 40 MW when driving, compared with the maximum power of locomotives used in the Russian Federation 1800 kW, which will reach a speed of 500 km / h or more.

The radial clearance is controlled by cooling the compressor, turbine and free turbine 2 casings, while the diameter of the stator D1 decreases and the gap δ also decreases (this is illustrated by the example of regulating the radial clearance in the compressor of Fig. 7).

The application of the invention allowed:

1. To facilitate (accelerate) the launch of a gas turbine locomotive power plant.

2. Improve the reliability of the power plant.

3. Improve the efficiency of the installation.

4. Ensure the safety of work.

5. Create conditions for transportation.

6. Provide maintainability.

Claims (13)

1. The power plant of a gas turbine locomotive containing a gas turbine engine, at the outlet of which a free turbine is installed, at the outlet of which an exhaust device is installed, characterized in that the gas turbine engine and a free turbine are mounted on a frame in a container having a cooling system combined with a radial regulation system clearances in a gas turbine engine and / or in a free turbine and with a fire extinguishing system. 2. The power plant of a gas turbine locomotive according to claim 1, characterized in that the container is made of two parts and has a longitudinal connector and hatches for inspection and replacement of units, and the frame is attached to the bottom of the container. 3. The power plant of a gas turbine locomotive according to claim 1 or 2, characterized in that the container is lined with heat and sound insulating material inside and / or outside. 4. The gas turbine locomotive power plant according to claim 1 or 2, characterized in that the front of the frame is rigidly attached to the bottom of the container, and the rear is axially movable. 5. The power plant of a gas turbine locomotive according to claim 1 or 2, characterized in that it comprises an oil cooling system with an air-oil heat exchanger. 6. The power plant of the gas turbine according to claim 1 or 2, characterized in that the electric generator is located at the entrance to the gas turbine engine. 7. The gas turbine locomotive power plant according to claim 1 or 2, characterized in that the electric generator is located at the outlet of the power turbine. 8. The power plant of the gas turbine according to claim 1 or 2, characterized in that it is made of modular design. 9. The power plant of a gas turbine locomotive according to claim 3, characterized in that it is made of modular design. 10. The power plant of a gas turbine according to claim 4, characterized in that it is made of modular design. 11. The power plant of a gas turbine according to claim 5, characterized in that it is made of modular design. 12. The power plant of a gas turbine according to claim 6, characterized in that it is made of modular design. 13. The power plant of a gas turbine according to claim 7, characterized in that it is made of modular design.

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