EP1681472A1 - Method for retrofitting a compressor - Google Patents

Abstract

The method is for the modification of a multi-stage compressor (101), whereby the rotor blades of the first rotor blade row (LA1) are exchanged for different rotor blades which have an identical blade profile (121) as the originals, and the blade angle of which differs from that (B' 10) of the original. The blades of at least one other blade row (LAN,LEN) located downstream of the second compressor stage are exchanged for different blades which have an identical blade profile (125,126) as the originals, and a blade angle different from that (B'N0, B"N0) of the originals. Independent claims are included for the following: (A) a compressor modified by the aforesaid method; and (B) a gas turbine unit including the aforesaid compressor.

Description

Technical area

The invention relates to a method for modifying a multi-stage compressor according to claim 1. Furthermore, it relates to a modified according to the specified method compressor and a gas turbine group, which comprises a so modified compressor.

State of the art

A modification of turbocompressors can be done by changing the blade angle of blade rows with a constant profile of the blades. The blade angle is usually defined as the angle that encloses the chord of the profile with the circumferential direction of the compressor. By this possibility of changing the geometry of a blade grid, for example, the mass flow can be increased without requiring a redesign of the airfoil. This is realized, for example, with adjustable Verdichterleitreihen and in particular with an adjustable Vorleitreihe a compressor. However, the implementation of a plurality of adjustable Verdichterleitreihen is relatively expensive.

Presentation of the invention

According to one aspect of the invention, a method for modifying a multi-stage compressor by re-scaling blades, that is to say the change of the blade angle, will now be given. The profile of the airfoil is retained. According to a more specific aspect of the invention, this possibility should be given without using adjustable blade rows. Another aspect of the invention is to increase the mass flow of the compressor, in an exemplary embodiment by as much as six percent over the compressor prior to modification. In a more specific embodiment, the increase of the mass flow should be achieved without reducing the flow stability in the compressor and / or due to the increased mass flow to provoke flow blockages in blade channels.

The method described in claim 1 is capable, among other advantageous effects, of meeting the requirements set forth above.

The method comprises exchanging the blades of the first compressor barrel row for changed blades, which have an identical blade profile and a blade angle that is different compared to the originally installed blades. In this way, the absorption capacity of the first compressor run series can be increased and, in particular, the compressor mass flow can be increased in conjunction with an adjustable preliminary guide row. A potentially deteriorated flow stability associated with the changed geometry of the blade lattice is counteracted by further varying the blade angle of at least one row of blades further downstream, and more particularly downstream of the second compressor stage. For this purpose, the blades of the at least one further row of blades are replaced by modified blades which have an identical airfoil profile as the original blades, and whose blade angle is different from that of the original blades. In one embodiment of the invention, the change of the blade angle in the further blade row is in the same direction as the change of the blade angle in the first compressor barrel row, that is, if the blade angle of the first compressor barrel row is increased, also the blade angle of the further blade row is increased, and if the Shovel angle of the first compressor run series is reduced, also the blade angle of the other blade row is reduced. An embodiment of the invention is characterized in that the blade geometry of the guide row of the first compressor stage is maintained unchanged, so that neither the airfoil profile nor the blade angle are changed.

Under a compressor stage while the arrangement of a compressor barrel and a downstream downstream Verdichterleitreihe is understand. This is to be understood in contrast to a turbine stage which comprises a guide row with a row of nozzles arranged downstream thereof. A row of flights comprises a blade ring or a blade grid, which comprises a plurality of rotor blades. These are also referred to as rotor components, for example rotor blading, rotor blade ring, or rotor blade grille and the like. A guide row comprises a blade ring or a blade grid, which comprises a plurality of guide vanes. These are also referred to as stator components, such as stator blading, stator blade ring, or stator blade grid, and the like.

A further development of the method specified here comprises exchanging the blades of the second compressor barrel row for changed blades, which have an identical airfoil profile as the original rotor blades, and whose blade angle is different from that of the original rotor blades. An embodiment of this development comprises maintaining the blade geometry of the guide row of the second compressor stage unchanged.

Developments of the method described here include, in at least one downstream of the second compressor stage arranged compressor stage to replace both the blades of the row and the blades of the Leitreihe against modified blades having an identical airfoil profile as the original blades, and their blade angle of the original blades is different, and / or the blades of at least one row of blades each downstream of the second compressor stage arranged compressor stage to replace changed blades having an identical airfoil profile as the original blades, and whose blade angle is different from that of the original blades.

In one embodiment of the method, the blade angles in the rows of blades, whose blades are replaced by changed blades, are adapted to one another such that the relative Enthalpy structure, based on the total Enthalpieaufbau in the compressor, in the individual compressor stages and / or in the individual blade rows relative to the unmodified compressor is kept substantially constant. Thus, it is possible to change the mass flow of the compressor, while maintaining the stability reserve against stall substantially unchanged.

An increase in the blade angle, which is defined as the angle which the chord of the airfoil profile encloses with the circumferential direction of the compressor, generally results in an increase in the mass flow. An application of the method described herein, in which originally installed blades are replaced by modified blades, in which the chords of the airfoils are oriented more towards the compressor axis than the originally installed blades, thus resulting in an application of the method for increasing the compressor mass flow. With an exemplary embodiment of the method, an increase in the compressor mass flow can be achieved by up to six percent without the stability reserve of the compressor being significantly changed.

The above-described embodiments of the method can of course be combined with each other.

The invention further comprises a compressor modified by the method described above. In particular, such a compressor comprises at least three axial compressor stages, and in a more specific embodiment it is a purely axial multi-stage compressor. Multi-stage purely axial turbocompressors are used, for example, as compressors of gas turbine groups; In this respect, the invention also includes a gas turbine group having a compressor modified by a method as described above.

Further advantageous and expedient developments of the invention will become apparent to those skilled in the light of the dependent claims and of embodiment shown below.

Short description of the drawing

The above-mentioned method is explained in more detail below with reference to an exemplary embodiment illustrated in the drawing. Show in detail

Figure 1 is a gas turbine group;

Figure 2 details of a multi-stage axial compressor; and

Figure 3 details of a modified multi-stage axial compressor.

Details that are not essential to understanding the invention have been omitted. The embodiment and the drawing are intended to better understand the method described above, and are not to be used to limit the invention characterized in the claims.

Ways to carry out the invention

FIG. 1 shows a gas turbine group 100. This includes a multi-stage axial turbocompressor 101, a combustor 102 and a turbine 103. The gas turbine group shaft 111 is drive-connected to a generator 104. The compressor 101 comprises a housing in which the static components of the compressor are arranged, and the shaft 111, on which the rotor components are arranged. The compressor shown as an example and simplified comprises a Vorleitreihe IGV, which may be equipped with adjustable vanes, and ten compressor stages 1 to 10. The number of compressor stages here is not limiting; The turbocompressors of modern gas turbine groups usually have a higher number of stages, for example 17 to 21. For an illustration of the invention, however, the representation with ten compressor stages is sufficient and clearer. The flow direction of the compressor is in the drawing from left to right. The first compressor stage comprises a blade row LA1 arranged on the shaft and a row of guide blades arranged downstream thereof in the housing LE1. All other compressor stages likewise each comprise a blade row with a row of guide blades arranged downstream thereof. In a manner known per se, each row of blades comprises a plurality of blades, each of which has a blade root and an airfoil in a manner also known per se.

FIG. 2 shows details of an exemplary compressor, as used, for example, in the gas turbine group from FIG. 1, in its original state, that is to say prior to a modification with the specified method. Shown are the first two compressor stages, comprising the row LA1 and the guide row LE1, and the row LA2 and the row LE2. Furthermore, an arbitrary compressor stage N arranged downstream of the second compressor stage is shown with the row LAN and the row LEN. The blades are labeled 121, 122, 123, 124, 125, and 126. In a view from radially outward, the airfoil profiles are discernible, as well as the blade angle, which is defined as the angle which encloses the chord of the airfoil profile with the circumferential direction of the compressor. The blade angle of the blades 121 of the first blade row LA1 is designated B _'10th The blade angle of the blades 122 of the first stator row LE1 is "means _{the 10th} of the blade angle of the blades 123 of the second blade row LA2 is designated B _'20th of the blade angle of the blades 124 of the second stator row LE2 is connected to B" denoted by B _twentieth The blade angle of the vanes 125 of the row LAN is denoted by B ' _N0 . The blade angle of the blades 126 of the guide row LEN is denoted by B " _N0 .

FIG. 3 shows the compressor from FIG. 2, which has been modified by the method described. The airfoil profiles of the blades in the illustrated blade rows are identical. Likewise, the blade angle has been retained in the guide rows LE1 of the first and LE2 of the second compressor stage. On the other hand, the bucket angle in the first LA1 series has been increased from B _'10 to B' ₁₁ . The bucket angle of the second row LA2 has been increased from B _'20 to B' ₂₁ . The chords are in these two rows now oriented more towards the axis of the compressor. Thus, the degree of locking of the respective blade grid is reduced, resulting in an increase of the compressor mass flow. In the LAN and LEN series, the blade angles are also increased from B ' _N0 and B " _N0 to B' _N1 and B"_N1; the airfoil profiles are each kept identical. This modification can also be made in other, not shown blade rows of the compressor. It is not necessary to always change the blade angles of the row and the guide row of a stage; Similarly, in one stage, only the blade angle of either the row of rows or the row of leaders may be changed. The modification of rows of blades arranged downstream of the second compressor stage causes on the one hand no flow blocking in these rows of blades due to the increased mass flow, and on the other hand that the enthalpy structure of the compressor is not disproportionately shifted in the first and second series of runs, otherwise the stability reserve against stall would diminish in the blade lattices of the first and second row of races.

Although not explicitly mentioned, it will be apparent to those skilled in the art that the above illustrations are analogously applicable to compressor blades in which the airfoils are variable over the blade height and in particular also for twisted blades known to those skilled in the art; the illustrations in FIGS. 2 and 3 then relate to a circumferential section.

LIST OF REFERENCE NUMBERS

0 preliminary series

1 first compressor stage

2 second compressor stage

3 third compressor stage

4 fourth compressor stage

5 fifth compressor stage

6 sixth compressor stage

7 seventh compressor stage

8th compressor stage

9 ninth compressor stage

10th compressor stage

100 gas turbo group

101 compressors

102 combustion chamber

103 turbine

104 generator

111 wave

112 housing

121 airfoil of the first run series

122 airfoil of the first guide row

123 airfoil of the second series

124 airfoil of the second Leitreihe

125 airfoil of the row N

126 airfoil of the guide row N

IGV pilot series

LA1 series of the first compressor stage

LE1 guide row of the first compressor stage

LA2 series of second compressor stage

LE2 guide row of the second compressor stage

LA3 series of third compressor stage

LE3 Leitreihe the third compressor stage

LA4 series of the fourth compressor stage

LE4 Leitreihe of the fourth compressor stage

LA5 series of fifth compressor stage

LE5 guide row of the fifth compressor stage

LA6 series of the sixth compressor stage

LE6 Leitreihe of the sixth compressor stage

LA7 series of the seventh compressor stage

LE7 Leitreihe of the seventh compressor stage

LA8 series of the eighth compressor stage

LE8 guide row of the eighth compressor stage

LA9 series of the ninth compressor stage

LE9 Leading the ninth compressor stage

LA10 series of the tenth compressor stage

LE10 Leitreihe of the tenth compressor stage

LAN run series of the compressor stage N

LEN guide series of compressor stage N

B _'10 original bucket angle in the first run row

B _'11 changed blade angle in the first run row

B " ₁₀ original bucket angle in the first guide row

B _'20 original bucket angle in the second run row

B _'21 changed blade angle in the second row

B " ₂₀ original bucket angle in the second guide row

B ' _N0 original bucket angle in the N series course

B ' _N1 changed blade angle in the row N stage

B " _N0 original bucket angle in the N series guide row

B " _N1 changed bucket angle in the N series guidance

Claims (15)

A method of modifying a multi-stage compressor (101) comprising exchanging the blades of the first compressor gallery (LA1) for changed blades having an identical airfoil profile (121) as the original blades and their blade angle (B _'11 ) from the blade angle ( B _'10 ) of the original blades, and to replace the blades of at least one further row of blades (LAN, LEN) downstream of the second compressor stage with changed blades having an identical airfoil profile (125, 126) as the original blades and their blade angle (B ' _N1 , B " _N1 ) is different from the blade angle (B' _N0 , B" _N0 ) of the original blades Method according to claim 1, characterized in that the blade geometry of the guide row (LE1) of the first compressor stage is maintained unchanged. Method according to one of claims 1 or 2, characterized in that the blades of the second compressor row (LA2) to replace changed blades having an identical airfoil profile (122) as the original blades, and whose blade angle (B _'21 ) from the blade angle ( B _'20 ) of the original blades is different. Method according to claim 3, characterized in that the blade geometry of the guide row (LE2) of the second compressor stage is maintained unchanged Method according to one of the preceding claims, wherein the further blade row is a blade row (LAN). Method according to one of the preceding claims, wherein the further blade row is a guide blade row (LEN). Method according to one of the preceding claims, characterized in that in at least one compressor stage arranged downstream of the second compressor stage, both the blades of the rotor row and the blades of the guide row are exchanged for modified blades having an identical airfoil profile as the original blades, and their blade angle of the different from the original shovels. Method according to one of the preceding claims, characterized in that the blades of at least one row of blades each compressor stages arranged downstream of the second compressor stage to replace changed blades having an identical airfoil profile as the original blades, and whose blade angle is different from that of the original blades Method according to one of the preceding claims, characterized in that the blade angles in the rows of blades whose blades are exchanged for changed blades are adjusted to one another in such a way that the relative enthalpy structure of the individual compressor stages is kept substantially constant. Method according to one of the preceding claims, characterized in that the blade angle of the modified blades is greater than the blade angle of the original blades, such that the chords of the airfoils of the changed blades are oriented more towards the axis of the compressor. Method according to one of the preceding claims for increasing the compressor mass flow. Compressor (101) modified by a method according to any one of the preceding claims. Compressor according to claim 12, comprising at least three axial compressor stages. Compressor according to one of claim 13 as a purely axial multi-stage compressor. Gas turbine group (100), comprising a compressor according to one of claims 12 to 14.

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