RU2569015C2 - Diffuser for fixed gas turbine plant - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: diffuser (20), in particular of the axial compressor, preferably of the fixed gas turbine plant. In the diffuser (20) a ring channel (17), having first cross-section area, goes into output space (21), having second larger cross-section area along the machine axis (31). The transition is performed by several steps (22a-c). The diffuser (20a) contains an external casing (23) and internal casing (24), between them through the diffuser (20a) the work medium flows. Steps (22a-c) in the cross-section area are made by steps with diameter of the internal casing (24).

EFFECT: improved efficiency of the diffuser, and increased total efficiency of the gas turbine plant.

6 cl, 5 dwg

Description

FIELD OF THE INVENTION

The invention relates to the field of stationary gas turbine plants. The invention relates to a diffuser, as claimed in the restrictive part of claim 1.

BACKGROUND

The prior art diffusers are known which are located at the outlet of stationary gas turbine units and serve to reduce the flow rate of gases leaving the gas turbine unit and increase the pressure in it, and therefore increase its efficiency (EP 0491966 A1 or US 2011/058939 A1, as well as the attached to this document, Fig. 1).

In the past, many proposals have been made to optimize the action of the diffuser located at the outlet of the gas turbine installation, and therefore, to increase the overall efficiency of the machine. So, in document EP 0265633 B1, it is proposed, inter alia, to divide the diffuser into several parts in the radial direction using guide baffles.

In accordance with the aforementioned US 2011/058939 A1, in order to improve the flow characteristics in the diffuser, an adjustable Coanda flow is introduced into the inner tapering part of the diffuser, by which the flow in the diffuser can be positively affected. The inner part of the diffuser - the core - narrows in the direction of flow without the formation of a step. Gas is supplied from an external source to the annular chamber inside the core, and from there it is injected using a series of slotted nozzles in the direction of movement of the hot exhaust gases parallel to the surface of the core. As a result of the well-known Coanda effect, the flow of said additional gas draws in hot exhaust gas, deflecting it in the direction of the core. The flow of exhaust gas is accelerated, moving along the contour of the surface of the core, which narrows in the direction of flow. In order to optimally affect the exhaust gas flow in the diffuser, it is necessary to supply additional gas, the mass of which is up to 4% of the exhaust gas mass, which entails significant costs.

In EP 0265633 B1, on the contrary, a cross-sectional area is proposed at the outlet of the diffuser with a sharp step, which is designated as a Carnot diffuser.

Although these measures can slightly improve the efficiency, the possibilities of exerting influence on the diffuser region are far from exhausted.

SUMMARY OF THE INVENTION

The objective of the invention is to provide a diffuser, in particular for an industrial gas turbine installation, which will easily increase the overall efficiency of the gas turbine installation.

These and other tasks are solved using a combination of features according to claim 1 of the claims.

The invention relates to a diffuser for a stationary gas turbine installation in which an annular channel having a first cross-sectional area passes into an output space having a second, large cross-sectional area along the axis of the machine. The diffuser is characterized in that the transition is carried out in several stages.

The first innovation of the invention is that the cross-sectional area inside the diffuser increases in two stages. The specified diffuser is especially simple.

The second innovation of the invention is that the diffuser is implemented as a Carnot diffuser.

The third innovation of the invention lies in the fact that the diffuser includes an outer casing and an inner casing between which the medium moves through the diffuser, and that steps in the cross-sectional area are formed by steps of the diameter of the inner casing.

A fourth innovation of the invention is that between the two adjacent steps there is an annular convex guide surface that converges on the cone in diameter, and that a circular opening is provided on the upstream step of the two steps through which the gas stream can flow out and move along the guide surfaces in the form of a Coanda flow. As a result, the flow in the diffuser can be positively affected.

Preferably, the guide surface is located between the penultimate and last stages of the diffuser.

The fifth innovation of the invention is that the diffuser is located at the outlet of an industrial gas turbine installation.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention will be described below with examples of its implementation, illustrated by drawings, in which:

FIG. 1 is a schematic view of a gas turbine plant with an exhaust diffuser, which are essentially known;

FIG. 2 is an internal view of a conventional Carnot diffuser;

FIG. 3 is an internal view of a multi-stage diffuser according to one embodiment of the invention, as opposed to the diffuser of FIG. 2;

FIG. 4 is a general view of a two-stage diffuser corresponding to another embodiment of the invention; and

FIG. 5 is an internal view of a two-stage diffuser controlled by a Coanda flow, in accordance with yet another embodiment of the invention.

DESCRIPTION OF THE PREFERRED EMBODIMENTS OF THE INVENTION

FIG. 1 illustrates a schematic view of a gas turbine plant with an exhaust diffuser according to the prior art. The gas turbine unit 10 shown in FIG. 1 includes a compressor 12 that draws in air and compresses it through an air inlet 11. Compressed air is supplied to the combustion chamber 13, where it participates in the combustion of fuel 14. The resulting hot gas expands in the turbine 15, located downstream, under operating conditions and then passes through a diffuser 16, which reduces its flow rate and increases the pressure.

In FIG. 2, an extremely simplified view shows the internal structure of a conventional Carnot diffuser. This diffuser 16 is made concentrically with respect to the axis 31 of the machine, and on the side of its inlet, the diffuser 16 includes an annular channel 17 into which the exhaust gas 19 enters from the turbine. An output space 21 is adjacent to the annular channel 17, the cross section of which significantly exceeds the cross-section of the annular channel 17, which facilitates the passage of flow through the space 21. In this example, the transition between the annular channel 17 and the output space 21 is made through a steep step 22, which characterizes the diffuser 16 as a Carnot diffuser. In the annular channel 17 can be located radial struts 18, which communicate with each other the inner part and the outer part of the diffuser 16 and at the same time serve to mix the flow.

According to the embodiment of the invention illustrated in FIG. 3, it is proposed to make the transition between the annular channel 17 and the outlet space 21 in the form of a series of steps, as in the diffuser 20. In the illustrated example, two steps are provided for this purpose - 22a and 22b. If necessary, one more step can be provided - 22 s (shown in dashed lines in Fig. 3). The number of steps is not limited from above. In the embodiment illustrated in FIG. 3, diameter steps that relate to steps 22a-c are limited to the inside of the diffuser 20. Similarly, steps of diameter can be provided on the outside of the diffuser.

Such a multi-stage internal circuit provides a pressure increase that can correspond to 0.1% of the turbine efficiency, which in the case of a gas turbine installation of the Alstom GT26 model means an increase in power by almost half a megawatt.

In practice, the corresponding diffuser looks, for example, as shown in FIG. 4. The diffuser 20a of FIG. 4 includes an annular outer casing 23 that surrounds the inner casing 24 in a concentric manner and together with the inner casing 24 restricts the flow channel. The inner casing 24 and the outer casing 23 are interconnected via radial struts 25. In the outlet region of the diffuser 20a, two rings 26 and 27 are arranged one after another in the longitudinal direction, which are offset from each other in diameter and thereby ensure multi-stage expansion of the diffuser 20a.

In addition to the multi-stage expansion of the flow penetrating the cross section, the flow characteristics in the diffuser can be influenced by the Coanda flow, as proposed, in principle, in document US 2011/058939 A1 mentioned in the introduction. To this end, an annular convex guide surface 28 is placed between the two steps 22a and 22b, which converges on a cone in diameter, as is the case with the diffuser 20b of FIG. 5. A circular opening 29 is provided on the upstream stage of the two stages 22a and 22b through which the gas stream can flow out and move along the guide surface 28 in the form of a Coanda stream 30. At the same time, gas for Coanda stream 30 can be supplied in various ways. However, in accordance with the invention and in contrast to what is said in the aforementioned document, it is necessary to exclude an external reference source for actively pumping additional gas. Given the correct placement of the components, the pressure parameters prevailing in the region of uneven transverse expansion of the diffuser should be used so that in the operating mode, the flow 30 near the wall automatically increases along the curved guide surface 28, while deflecting the parallel exhaust gas flow 19. The static pressure P ₂ behind the annular element 27 exceeds the inlet pressure P ₁ on the circular hole due to the deceleration of the flow due to its transverse expansion. Thus, a stream 32 arises which moves from the high pressure region to the low pressure region. If the diffuser contains more than two stages, then the Coanda stream is preferably fed between the penultimate and last stages.

Claims (6)

1. A diffuser (20, 20a, 20b) for a stationary gas turbine installation in which an annular channel (17) having a first cross-sectional area passes into an outlet space (21) having a second, large cross-sectional area along the machine axis (31) characterized in that said transition is carried out in several stages (22a-c), wherein the diffuser (20a) comprises an external casing (23) and an internal casing (24), between which the working medium moves through the diffuser (20a), and the stages ( 22a-c) in the cross-sectional area formed by steps of diameter inner case (24). 2. The diffuser according to claim 1, characterized in that the cross-sectional area inside the diffuser (20, 20a, 20b) increases in two stages (22a, 22b). 3. A diffuser according to claim 1 or 2, characterized in that the diffuser (20, 20a, 20b) is implemented as a Carnot diffuser. 4. The diffuser according to claim 1, characterized in that between the two adjacent steps (22a, 22b) there is an annular convex guide surface (28), which converges on a cone in diameter, while on the upstream stage from two steps (22a 22b) a circular opening (29) is provided through which the gas stream can flow out and move along the guide surface (28) in the form of a Coanda stream (30). 5. The diffuser according to claim 4, characterized in that the guide surface (28) is located between the penultimate and last stages of the diffuser (20b). 6. A diffuser according to claim 1, characterized in that the diffuser (20, 20a, 20b) is located at the outlet of the stationary gas turbine installation (10).

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