DE102011118735A1 - DIFFUSER, ESPECIALLY FOR AN AXIAL FLOW MACHINE - Google Patents

Abstract

The invention relates to a diffuser (20), in particular for an axial flow machine, preferably a stationary gas turbine, which diffuser (20) along an engine axis (31) from an annular channel (17) having a first cross-sectional area in an exit space (21) with a second , larger cross-sectional area passes. An improved efficiency is achieved in that the transition takes place in several stages (22a-c) and in that an annular gap (29) is provided, through which a gas stream can exit and flow along the guide surface (28) as Coanda flow (30) ,

Description

TECHNICAL AREA

The present invention relates to the field of axial flow machines. It relates to a diffuser according to the preamble of claim 1.

STATE OF THE ART

Diffusers located at the exit of stationary gas turbines and designed to reduce the flow rate of gases coming out of the turbine and to create pressure build-up to improve the efficiency of the gas turbine have long been known in the art (see for example US Pat pamphlet EP 0 491 966 A1 or the publication US 2011/058939 A1 with the local 1 ).

In the past, various proposals have been made to improve the effect of the diffuser at the exit of a gas turbine and thus the overall efficiency of the engine. So is among other things in the document EP 0 265 633 B1 proposed to divide the diffuser in the radial direction by means of flow-guiding baffles into several partial diffusers.

In the already mentioned US 2011/058939 A1 To improve the flow conditions in the diffuser at the inner tapered part of the diffuser, a controllable Coanda flow is provided, with which the flow in the diffuser can be favorably influenced. The inner part of the diffuser, the hub, tapers downstream without forming a step. From an external source, a gas is led to an annular chamber in the hub and injected from there via a number of slot nozzles in the flow direction of the hot exhaust gases parallel to the surface of the hub. Due to the known Coanda effect, this additional gas stream sucks hot exhaust gas and deflects it towards the hub. The exhaust flow is accelerated there and conforms to the surface of the downstream tapered hub. In order to achieve a desired effect on the exhaust gas flow in the diffuser, up to 4% of the exhaust gas mass flow must be injected with additional gas, which amounts to a not inconsiderable expense. In the EP 0 265 633 B1 In contrast, an abrupt transition in the cross-sectional area is provided at the outlet of the diffuser, which is referred to as Carnot diffuser.

Although these measures bring about some improvements in the efficiency, the possibilities of influencing the area of the diffuser are far from exhausted.

PRESENTATION OF THE INVENTION

It is therefore an object of the invention to provide a diffuser, in particular for an industrial gas turbine, which leads in a simple manner to a further improvement in the overall efficiency of the gas turbine.

These and other objects are achieved by the entirety of the features of claim 1.

The invention is based on a diffuser, in particular for an axial flow machine, preferably a stationary gas turbine, which diffuser merges along an engine axis from an annular channel with a first cross-sectional area into an outlet space with a second, larger cross-sectional area. It is characterized by the fact that the transition takes place in several stages.

A first embodiment of the invention is characterized in that the cross-sectional area within the diffuser increases in two stages. This diffuser is particularly simple in construction.

According to another embodiment of the invention, the diffuser is designed as a Carnot diffuser.

Another embodiment of the invention is characterized in that the diffuser comprises an outer jacket and an inner jacket, between which the medium flows through the diffuser, and that the steps in the cross-sectional area are produced by diameter steps on the inner jacket.

Another embodiment of the invention is characterized in that an annular, convexly curved, diameter-tapering guide surface is arranged between two adjacent stages, and that an annular gap is provided at the upstream of the two stages, through which a gas stream emerges and as Coanda Flow can flow along the guide surface. As a result, the flow in the diffuser can be favorably influenced.

Preferably, the baffle is disposed between the penultimate and last stages of the diffuser.

Yet another embodiment of the invention is characterized in that the diffuser is arranged at the outlet of an industrial gas turbine.

BRIEF EXPLANATION OF THE FIGURES

The invention will be explained in more detail with reference to embodiments in conjunction with the drawings. Show it

1 the schematic structure of a gas turbine with exhaust diffuser, as it is known per se;

2 the internal structure of a conventional Carnot diffuser;

3 compared to 2 the internal structure of a multi-stage diffuser according to an embodiment of the invention;

4 a side perspective view of a 2-stage diffuser according to another embodiment of the invention; and

5 the internal structure of a 2-stage diffuser with Coanda control according to another embodiment of the invention.

WAYS FOR CARRYING OUT THE INVENTION

In 1 the schematic structure of a gas turbine with exhaust diffuser is reproduced, as it is known from the prior art. In the 1 illustrated gas turbine 10 includes a compressor 12 that has an air intake 11 Air sucks and compacts. The compressed air becomes a combustion chamber 13 fed and there for the combustion of a fuel 14 used. The resulting hot gas is in a subsequent turbine 15 Relaxed under work and then flows through a diffuser 16 in order to lose flow velocity there and to cause a pressure build-up.

The internal structure of a conventional Carnot diffuser is in 2 rendered very simplified. The local diffuser 16 concentric to a machine axis 31 is formed, the input side comprises an annular channel 17 over which the exhaust 19 the turbine into the diffuser 16 flows. To the ring channel 17 with its comparatively small cross-sectional area closes an exit space 21 on, which has a much larger cross-sectional area for the flow. The transition between ring channel 17 and exit space 21 takes place in this example by an abrupt step 22 that the diffuser 16 characterized as Carnot diffuser. In the ring channel 17 can radial struts 18 be arranged, the inner part and outer part of the diffuser 16 connect and at the same time serve to direct the flow.

In contrast, proposes now the invention, according to the in 3 illustrated embodiment in a diffuser 20 the transition between ring channel 17 and exit space 21 train in multiple stages. In the example shown are two stages 22a and 22b intended. Another level 22c (in 3 dashed lines) is optional. However, the number of levels is not limited to the top. The ones with the steps 22a -C associated diameter jumps are limited in the embodiment of 3 on the inner part of the diffuser 20 , But it is equally well conceivable to provide diameter jumps on the outer part of the diffuser.

With such a multi-stepped inner contour results in a pressure build-up gain, which can be at 0.1% of turbine efficiency and in a gas turbine GT26 type of the Applicant means a power gain of almost half a megawatt.

In practice, a corresponding diffuser, for example, looks like in 4 played. The diffuser 20a of the 4 includes an annular outer jacket 23 , concentrically an inner shell 24 encloses and together with the inner shell 24 a flow channel limited. inner sheath 24 and outer jacket 23 are by radial struts 25 connected. At the exit of the diffuser 20a are in the axial direction one behind the other two graduated rings in diameter 26 and 27 arranged through which the multi-stepped extension of the diffuser 20a is effected.

In addition to the multi-stage expansion of the flow cross-section influencing the flow conditions in the diffuser can be done by a Coanda flow, as in principle in the cited document US 2011/058939 A1 has been proposed. For this purpose is according to 5 with a diffuser 20b between two stages 22a and 22b an annular, convexly curved, diameter-tapered guide surface 28 arranged. At the upstream of the two stages 22a and 22b is an annular gap 29 provided, through which a gas flow escape and as Coanda flow 30 at the guide surface 28 can flow along. The gas supply for the Coanda flow 30 can be done in different ways. In contrast to the above-mentioned document, according to the invention, however, an external source of supply for an actively injected additional gas should be dispensed with. By an appropriate arrangement of the components, the prevailing in the area of the sudden cross-sectional widening of the diffuser pressure ratios should be exploited in such a way that during operation automatically a wall flow 30 along the curved guide surface 28 builds up the parallel exhaust gas flow 19 distracting. The static pressure p ₂ after the ring body 27 is due to the flow slowing through the Cross-sectional widening higher than the inlet pressure p ₁ at the annular gap. Accordingly, a flow forms 32 from the higher pressure area to the lower one. If there are more than two stages in the diffuser, the Coanda flow is preferably used between the penultimate and last stages.

LIST OF REFERENCE NUMBERS

10

gas turbine

11

air intake

12

compressor

13

combustion chamber

14

fuel

15

turbine

16, 20

diffuser

17

annular channel

18, 25

strut

19

exhaust

20a, b

diffuser

21

exit space

22a-c

Stage (cross-sectional area)

23

sheath

24

inner sheath

26, 27

ring

28

Guide surface (convexly curved)

29

annular gap

30

Coanda flow

31

machine axis

32

backwash

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• EP 0491966 A1 [0002]
• US 2011/058939 A1 [0002, 0004, 0026]
• EP 0265633 B1 [0003, 0004]

Claims (7)

Diffuser ( 20 . 20a . 20b ), in particular for an axial flow machine, preferably a stationary gas turbine ( 10 ), which diffuser ( 20 . 20a . 20b ) along a machine axis ( 31 ) of an annular channel ( 17 ) having a first cross-sectional area in an exit space ( 21 ) merges with a second, larger cross-sectional area, characterized in that the transition in several stages ( 22a -C). Diffuser according to claim 1, characterized in that the cross-sectional area within the diffuser ( 20 . 20a . 20b ) in two stages ( 22a . 22b ) enlarged. Diffuser according to claim 1 or 2, characterized in that the diffuser ( 20 . 20a . 20b ) is designed as a Carnot diffuser. Diffuser according to one of claims 1-3, characterized in that the diffuser ( 20a ) an outer jacket ( 23 ) and an inner jacket ( 24 ), between which the medium by diffuser ( 20a ) and that the steps ( 22a C) in the cross-sectional area by diameter steps on the inner shell ( 24 ) be generated. Diffuser according to one of claims 1-4, characterized in that between two adjacent stages ( 22a . 22b ) an annular, convexly curved, diameter-reducing guide surface ( 28 ) and that at the upstream of the two stages ( 22a . 22b ) an annular gap ( 29 ) is provided, through which a gas flow escape and as Coanda flow ( 30 ) at the guide surface ( 28 ) can flow along. Diffuser according to claim 5, characterized in that the guide surface ( 28 ) between the penultimate and the last stage of the diffuser ( 20b ) is arranged. Diffuser according to one of claims 1-6, characterized in that the diffuser ( 20 . 20a . 20b ) at the exit of a stationary gas turbine ( 10 ) is arranged.

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