RU2305789C2 - Gas-turbine plant - Google Patents

Abstract

FIELD: mechanical engineering; gas-turbine plants.

SUBSTANCE: proposed gas-turbine plant includes low-pressure compressor at input, power turbine at output, intermediate housing with separation of flows between compressors and channels of outer and inner loops. Inner loop contains high-pressure compressor with mixer at output. Input of channel of outer loop is connected with output of low-pressure compressor, and output, with external side of mixer. Ratio of area of channel of outer loop at flow separator in intermediate housing between compressors in gas-turbine plant to area of channel of inner loop at flow separator in intermediate housing between compressors in gas-turbine plant is within 0.1-3. Ratio of area of channel of outer loop at output of mixer to area of channel of inner loop at output of mixer is within 0.1-2.5. Number of stages of free power turbine is 1-3.

EFFECT: improved reliability and increased efficiency of plant at minimum cost owing to reduction of vibration stresses of turbine working blades and provision of uniform cooling of outer housings.

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Description

The invention relates to gas turbine units for driving an external load, mainly an electric generator in a power plant, or for a mechanical drive.

Known gas turbine installation, including a low-pressure compressor, high-pressure compressor and a multi-stage turbine [V.A. Schwartz. Designing gas turbine units, "Mechanical Engineering", Moscow, 1970, p. 346, Fig. 248].

The disadvantage of this design is its high cost due to the large number of stages of the turbine.

Closest to the claimed gas turbine installation, which includes a low-pressure compressor at the inlet, an intermediate casing between the compressors, a high-pressure compressor, a combustion chamber, a high-pressure turbine, a low-pressure turbine with a mixer at the outlet, and an external circuit channel, the input of which is connected to the output of the low-pressure compressor, and the output to the outside of the mixer, and a power turbine at the outlet of the unit [RF Patent No. 2224900, F02C 6/00, F02K 3/02, 2004].

A disadvantage of the known gas turbine installation, adopted as a prototype, is its low reliability and efficiency of the installation due to the high level of vibration stresses of the turbine blades and the insufficient uniformity of cooling of the outer casings.

The technical problem to which the claimed invention is directed is to increase the reliability and efficiency of the installation at its minimum cost by reducing the vibration stresses of the working blades of a free turbine and increasing the uniformity of cooling of the outer casings. This task is performed by calculating the optimal ratio of the areas of the channels of the external and internal circuits by the flow separator in the intermediate casing between the compressors, the optimal ratio of the areas of the channels of the external and internal circuits by the mixer, as well as the number of stages of the power turbine.

The essence of the invention lies in the fact that in a gas turbine installation comprising a low-pressure compressor at the inlet, a power turbine at the outlet, an intermediate housing between the compressors with a flow splitter, channels of the external and internal circuits, the internal circuit comprising a high-pressure compressor with a mixer at the output the channel of the external circuit is connected to the output of the low pressure compressor, and the output to the external side of the mixer, according to the invention F ₁ / F ₂ = 0.1 ÷ 3, F ₃ / F ₄ = 0.1 ÷ 2.5 and Z = 1 ÷ 3 where

F ₁ - the area of the channel of the external circuit along the separator flows in the intermediate between the compressors casing of a gas turbine installation;

F ₂ - the area of the channel of the internal circuit by the separator flows in the intermediate between the compressors of the gas turbine unit;

F ₃ - the channel area of the outer circuit at the outlet of the mixer;

F ₄ - the channel area of the inner circuit at the outlet of the mixer;

Z is the number of stages of a power free turbine.

The amount of air flowing through the channels of the external and internal circuits is determined by the radial location of the air flow separator in the housing intermediate between the compressors, i.e. the ratio of the areas F ₁ and F ₂ . So when F ₁ / F ₂ <0.1, the reliability and efficiency of a gas turbine installation decreases due to an increase in the temperature of the outer casings of the power turbine and an increase in the radial gaps between the stator and the rotor of this turbine, while the number of stages of the power free turbine increases due to an increase in its specific work , i.e. work performed by one kilogram of gas or air on the turbine, which leads to an increase in the cost of a free power turbine and gas turbine installation.

In the case when F ₁ / F ₂ > 3, a decrease in the efficiency, reliability and power of the gas turbine installation is observed, and the cost of the power turbine increases due to an increase in the outer diameter of the power turbine and an increase in stresses in the root sections of the working blade of this turbine.

To increase the reliability of a power free turbine by minimizing vibration stresses in its working blades, the gas and air flow at its inlet should have maximum uniformity in the circumferential and radial directions, which is facilitated by the same level of air pressure at the outlet of the channel of the external circuit and gas from the channel of the internal circuit, which determined by the ratio of the areas F ₃ and F ₄ at the outlet of the mixer. The reliability of the power free turbine also increases with decreasing temperature of its outer casing.

At F ₃ / F ₄ <0.1, the reliability of the gas turbine installation decreases due to the increased temperature of the outer casing of the power turbine, and at F ₃ / F ₄ > 2.5 the reliability of the gas turbine installation decreases due to the increased vibration stresses in the working blades of the power turbine due to increased unevenness of the air-gas flow at its inlet.

Reducing the specific work on the power free turbine allows you to get high efficiency with a minimum number of stages, thereby minimizing its cost.

This is especially true for a direct gearless drive of an electric generator, i.e. at revolutions of the power free turbine n = 3000 rpm Moreover, the number of its steps Z does not exceed three. In the case of a mechanical drive, i.e. at higher speeds of the power turbine Z = 1 ÷ 2.

At Z> 3, the cost increases and the reliability of the power free turbine decreases due to an increase in the number of expensive parts, especially the disks of working and nozzle blades.

Figure 1 shows a longitudinal section of a gas turbine installation, figure 2 - element I in figure 1 in an enlarged view, and figure 3 shows element II in figure 1 in an enlarged view.

The gas turbine unit 1 consists of a low pressure compressor 2, an inlet 3 of the intermediate casing 4, as well as a high pressure compressor 6 located in the internal circuit 5, a combustion chamber 7, a high pressure turbine 8, a low pressure turbine 9 with a mixer 10 at its outlet, from the channel external circuit 11, the input 12 of which is connected to the output 13 of the low pressure compressor 2, and the output to the external side 14 of the mixer 15 installed at the outlet of the low pressure turbine 9.

At the exit of the gas turbine installation 1, a power free turbine 16, common for the internal 5 and external 11 circuits, is established, consisting of the first 17 and second 18 stages. Net power from the turbine 16 is removed using the shaft 19.

In the intermediate casing 4, located between the low-pressure compressor 2 and the high-pressure compressor 6, a stream separator 20 is installed, separating the air stream 21 from the output 13 of the low-pressure compressor 2 to the air stream 22 at the inlet 12 of the channel of the outer circuit 11 and to the air stream 23 the inlet 24 of the high-pressure compressor 6 and, accordingly, to the internal circuit 5.

The radial position of the flow separator 20 determines the ratio of the areas of the channels at the inlet of the outer 11 (F ₁ ) and inner 5 (F ₂ ) circuits and, accordingly, the ratio of the air flow rates 22 and 23 along these circuits.

The mixer 15 at the outlet 24 is made with a passage area F ₃ along the outer contour and with a passage area F ₄ along the inner contour, and the channel 25 is connected to a power free turbine 16.

This device works as follows.

During the operation of the gas turbine unit 1, air through the inlet 3 enters the low-pressure compressor 2, at the outlet of which, with the help of the flow separator 20 in the intermediate casing 4, it is partially directed to the channel of the external circuit 11.

The remaining air enters the channel of the internal circuit 5, where it is compressed in the high-pressure compressor 6. The gas obtained as a result of combustion in the combustion chamber 7 expands and does useful work in the high-pressure turbine 8 and in the low-pressure turbine 9, which rotate the high-pressure compressor 6 and a low pressure compressor 9, respectively.

At the outlet of the mixer 15, the air from the channel of the external circuit 11 and the gas from the low pressure turbine 9 are partially mixed and through the channel 25 enter the free power turbine 16, where they perform useful work. The power from the free power turbine 16 is transmitted to the consumer using the shaft 19.

With a decrease in the operating modes of the gas turbine unit 1, the decrease in the rotor speed of the low pressure compressor 2 due to the high inertia is slower than the decrease in the speed of the rotor of the high pressure compressor 6, but this does not lead to a decrease in the gas-dynamic stability reserves and surging of the low-pressure compressor 2, since there are surpluses air at the outlet through the channel of the outer circuit 11 and the mixer 15 enter the power turbine 16 and are discharged into the atmosphere through an exhaust system (not shown). That is, in this design, to ensure the necessary reserves of gas-dynamic stability of the low-pressure compressor 2, no additional mechanization means are required (bypass valves, rotary guide vanes, etc.), which also increases the reliability of the gas turbine unit 1 as a whole.

The optimal ratio of the areas F ₁ / F _{2 of the} channels 11 and 5 of the external and internal circuits allows, by blowing air 22, to ensure the minimum temperatures of the outer casings of the compressor 6, the combustion chamber 7, and also the turbines 8, 9 and 16, providing a reduction in the radial clearance between the rotor and the stator of the compressor 6 and turbines 8, 9 and 16. Simultaneously, spurious leaks from the channel of the internal circuit 5 at the joints between the compressor housings 6, the combustion chamber 7 and turbines 8, 9 are “captured” in the channel of the external circuit 11 and then “triggered” into power freedom bottom turbine 16, which, due to the reduction in the specific work of the gas-air mixture flowing through it, is performed with a minimum number of stages, which reduces its cost.

Due to the reduced temperature of the air 22 flowing in the channel of the outer circuit 11, the temperature of the outer shells of this channel is minimal, which increases the reliability of these shells and reduces thermal and acoustic emissions into the external environment.

Claims (1)

A gas turbine installation including a low-pressure compressor inlet, a power turbine at the outlet, an intermediate housing between the compressors with a flow separator, channels of external and internal circuits, the internal circuit containing a high-pressure compressor with a mixer at the output, the channel input of the external circuit connected to the output of the low compressor pressure, and the output is with the outside of the mixer, characterized in that F ₁ / F ₂ = 0.1-3, F ₃ / F ₄ = 0.1-2.5 and Z = 1-3, where F ₁ - the area of the channel of the external circuit along the separator flows in the intermediate between the compressors casing of a gas turbine installation; F ₂ - the area of the channel of the internal circuit by the separator flows in the intermediate between the compressors of the gas turbine unit; F ₃ - the channel area of the outer circuit at the outlet of the mixer; F ₄ - the channel area of the inner circuit at the outlet of the mixer; Z is the number of stages of a power free turbine.

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