EP2603669A1 - Blade arrangement and associated gas turbine - Google Patents

Abstract

The invention relates to a blade arrangement (11) with a rotor (12) and a plurality of blades (14) which are distributed in a ring (10) along the circumference (U) of the rotor (12), wherein two immediately adjacent blades (14) of the ring (10) form a blade pair (a, b, b' , b' ', d, e, h), between the blades (14) of which a damping element (A, B, B', B' ', D, E, H) is arranged, and wherein the respective damping element (A, B, B', B", D, E, H) comes into contact with the two blades (14) of the blade pair (a, b, b', b' ', d, e, h) assigned to them during a rotation of the rotor (12) about a rotor axis as a result of a centrifugal force which acts in the radial direction (R). In order to bring about frequency detuning of the oscillation properties of blades (14), as a result of which machining of the turbine blade (22) becomes unnecessary, it is proposed that the blade ring (10) has at least two blade pairs (a, b, b', b' ', d, e, h) with different damping elements (A, B, B', B' ', D, E, H).

Description

description

SHOVEL ARRANGEMENT AND ASSOCIATED GAS TURBINE

The invention relates to a blade arrangement, ^comprising a rotor and a plurality of blades distributed along the circumference of the rotor in a ring, wherein two immediately adjacent blades of the ring form a pair of blades, between the blades of a damping element is arranged and where ^¬ by acting in the radial direction centrifugal force about a rotor axis occurs at a rotation of the rotor the jewei ^¬ celled damping element with the two blades of it supplied ^¬ arranged blade pair in contact.

It is known blade assemblies, which are used in fluid machines such as gas turbines, to be provided with Dämpfungsele ^¬ elements. These serve to dampen unwanted bending and torsional vibrations that can occur during operation in the turbomachine by different suggestions. In this way, HCF damage (abbreviation for "high cycle fatigue") caused by high oscillation amplitudes can be avoided, which can lead to premature material fatigue and to a shortened service life of the blades or of the blade arrangement Loose bodies are generally used as damping elements, which in the state of rest initially rest between the blade roots of the blades on the rotor or on corresponding support structures and, during operation of the rotor, press against the underside of the blade platforms of adjacent blades due to the centrifugal force acting in the radial direction be. stands at the same time with the two adjacent blade platforms in contact Every damping element. in this way, the kinetic energy of an evoked on ^¬ due to vibration relative movement between the blades can be converted into heat energy due to the friction between the respective blade platforms and the adjacent damping element. This dampens the oscillations ^¬ conditions and overall leads to reduced vibration ^¬ load the blade assembly. From the document EP 1154125 A2 a Schaufelanord ^¬ voltage is known, in which at least two damping elements Zvi ^¬ rule adjacent blades are arranged in the circumferential direction of the rotor one behind the other in order to achieve an effective damping of the entire blade assembly. The magazine disclosed in this pressure damping elements are made of soft interdependent ^¬ forming mold in order to dampen possible a plurality of different vibration modes. About the itself between the damping elements and the blades, and also on the forming between the individual Dämpfungselemen- contact areas can be converted to vibration damping by frictional vibration energy in heat energy ^¬ converted. However, the contact areas formed between the individual damping elements only have the form of a line contact, with which an only moderately pronounced damping effect is associated.

Other cross-sectional shapes of dampers are also known. The invention has for its object to provide a Schaufelanord ^¬ tion with damping elements, damped with the unwanted vibrations more effectively and the inclination of the blades can be reduced to vibrate due to excitation or even avoided.

This object is achieved by a blade arrangement according to the features of claim 1.

According to the invention, it is provided in the case of the blade arrangement mentioned at the beginning that the blade ring has at least two

Having pairs of blades with different damping elements. The invention is based on the finding that the coupling of the blades with damping elements also increases the natural frequencies in relation to the freestanding blades. When using identical damping elements thus all blades of a blade ring are detuned in identi ^¬ cal dimensions. As a result, identical blades with inherent identical frequencies for different vibration modes behave in the blade ring as if the respective blades have different natural frequencies for the vibration modes, but uncoupled. By using different damping elements within a blade ring, the size of the natural frequencies of adjacent blades can be adjusted so that immediately adjacent blades differ significantly in terms of their natural frequencies. This makes it possible to obtain a blade ring, the blades despite identical imple mentation form (apart from the manufacturing tolerances) and thus identical natural frequency (apart from the manufacturing tolerances and each considered by itself) in the wreath itself

vibrationally behave as if they

have different natural frequencies. In other words: By using the different ones

Damping elements, the natural frequencies of the arranged in the ring blades can be adjusted. Even in the case of non-synchronous excitation, they experience less excitation and thus react with a lower vibrational response, significantly reducing the tendency to flutter.

In operation, the damping elements are pressed against the lower side of adjacent blade platforms by blades by the centrifugal force. As a result of the relative movements Benach ^¬ barter blades causes friction between the damper and the blade platform, causing a coupling. The finding is based on the fact that in addition to the dissipation also causes a frequency shift of the natural frequencies of adjacent blades by the coupling. This effect can be used to preferentially alternately ^detune the blades ^{alternie ¬} . The adjacent blades react despite identical imple mentation form only because of

different damping elements such as blades with

different natural frequencies. Disgusted like that

Blades are particularly prone to flutter, especially when they are detuned alternately. In addition, the achievable with the damping elements stroke of the frequency shift is significantly greater than in the previous measures. Thus, a blade ring according to the invention has a significantly lower tendency to flutter than blade rings with blades, in which the blades themselves have different natural frequencies. In this respect, the blade ring according to the invention due to the use of different damping elements between a pair of blades is much more resistant to self-excited vibrations and the so-called flutter than conventional blade rings.

As a result, the different damping elements may replace the otherwise common and conventional means of adjusting natural frequencies, also known as "mistuning." These include, for example, shortening the trailing edge on the blade tip, grinding the blade profile, or drilling blade tip side holes in the blade. the invention has the particular advantage that assigned by the Mistunen of the blades with the two, each blade damping elements can remain the blade profile of the respective blade unchanged and thus no Perfor ^¬ manceverluste, neither in the level nor in the Strömungsma ^¬ machine, as in shortening the trailing edge, accompanied. the previous measures for adjusting the natural frequencies of the blades may be dispensed with. thus occurs a time and cost saving one as the iterative process of repeatable ^¬ th machining of blades completely entfa with repeated vibration measurements can.

Advantageous embodiments of the invention are specified in the subclaims. According to a first advantageous embodiment of the invention, each blade of the blade ring to two pairs of blades arranged, wherein two or more groups are provided by pairs of blades, within which the damping elements are ever ^¬ Weil identical and their damping elements differ from group to group. Preferably, a first group and a second group of pairs of blades are provided, and if the number of blades of the blade ring makes this possible, each pair of blades of one group in the circumferential direction is adjacent to one pair of blades of the other group. Unless the number of blades makes this possible, only a majority of the blades of the blade ring is arranged in the order given. As a result, an at least largely circulating ABAB series of blade pairs or damping elements is specified, which applies to the following advantageous embodiments in an analogous manner. The ABAB series of different damping elements already leads to a shift in the natural frequencies of the blades, since the damper elements which abut each other on a blade on both sides are connected in parallel according to a set model of Er. In principle, the individual parallel circuits of damping elements do not act differently. However, since the platforms on both sides of the airfoil, ie, the pressure side platform side and the suction side platform side, differ in shape from each other, their contact areas for the Dämpfungsele ^¬ elements each have different angles and a difference ^¬ union distance to the gravity line of the blades. This effect is reinforced by the angle of attack of the foot axis - with respect to the machine axis. This results from blade to blade slightly varying Koppelsteifigkei th. Thus, even the alternating arrangement of two different damping elements already leads to a shift environment of the natural frequencies of immediately adjacent blades.

A particularly preferred embodiment provides that a first group and a second group of blade pairs pre wherein each vane pair of the first group is adjacent to a vane pair of the first group and a vane pair of the second group (AABBAABB series). In this way, a higher frequency detuning is achieved than in the ABAB series, since the results from the equivalent model Kop ^¬ pelsteifigkeiten a blade to the neighboring blade are significantly different.

An equally effective frequency detuning can be achieved if a first group, a second group and a third group of pairs of blades are provided, wherein each pair of blades is adjacent to one of the three groups of two pairs of blades, which respectively belong to one of the two other groups (ABCABC-). Line ) .

Preferably, the different damping elements differ in terms of size, mass, the cross-sectional contour of the material and / or the coupling contact with the blades. Such damping elements can be produced with little effort, without adapting the casting and the contour of blades for the different groups. For example, the damping elements differ in their geometric shape. Thus, with suitably shaped damping elements and vibration modes can be effectively damped, which can not be effectively damped with the same design of all damping elements. Alternatively or additionally, the damping elements can also differ in their masses to effectively damp by combining with suitable geometric shapes as large a number of different vibration modes. Furthermore, by using damping elements made of different materials, the friction conditions (coefficient of friction, roughness) in the contact areas can be influenced, in order to enable targeted damping of several modes, even in increased frequency ranges. To the damping elements suitable between adjacent

To arrange blades, they are preferably rod-shaped.

In a specific embodiment of the invention

Blade assembly is the damping element of a Schaufelpaa ^¬ res multi-part design. It comprises - seen in the circumferential direction of the rotor - two (or more) successively arranged sub-elements, which are preferably rod-shaped. For example, one of the partial elements ^¬ a cross-section in the shape of a wedge and the other part element has a cross section in the form of a quarter circle. In particular ^¬ by matched-cross-sectional shapes of the damping elements and their parts, the inventions ^¬ inventive advantages can be achieved particularly efficient.

In a further concrete development, the damping elements are made of steel or ceramic, so mate- rials, with which an effective damping can be realized.

Hereinafter, an embodiment of a erfindungsge ^¬ MAESSEN blade assembly is explained in detail with reference to the accompanying drawings, in which

1 shows the axial view of a section of the

 Winding a blade ring of an axial turbomachine with arranged between the blades damping elements according to a first embodiment,

FIG 2,4,5,6,7 the detail according to FIG 1, but with under ^¬ retired union damping elements according to other embodiments and

3 shows a mechanical replacement model on the Kopp ^¬ ment of the blades of the blade ring with the help of the damping elements. In FIG. 1, a part of the rotor blade ring 10 is shown by blades 14, which are distributed on a rotor 12 along the circumference U, of an axial turbomachine (not shown). The axial turbomachine can be designed, for example, as a compressor, steam turbine or stationary gas turbine, which comprises the blade arrangement 11 with the rim 10 of blades 14. These each have a blade root 16 for attachment of the respective blade 14 on the rotor 12. The blade root 16 is dovetail-shaped or fir tree-shaped in a known manner. For positive fastening to the rotor 12, the latter is inserted into holding grooves of the rotor 12 which correspond to the blade root 16, so that the blades 14 are held securely when the rotor 12 rotates. The retaining grooves and thus the

Blade feet 16 extend mainly in the axial direction and are inclined with respect to a machine axis at an angle of attack.

To the outside, the blade root 16 merges into a blade neck (not further described), to which a platform 18 adjoins. The platform surface 20 limits the Strö ^¬ flow duct of the axial turbomachine. On the platform surface 20, an aerodynamic curved blade 22 is arranged freely ^¬ standing.

According to a first embodiment, on the underside of the platform 18 facing the blade root 16 between the

Platforms 18 of immediately adjacent blades 14 provided either type A or type A damping elements. Both types A, B of damping elements are rod-shaped, for example as damper wires. After in FIG 1 is provided ^¬ disclosed embodiment have the damping elements A, B each have a circular cross-section. However, the type A damping ^elements have a larger diameter than the type B damping ^elements . Both Dämpfungsele ^¬ elements A, B are therefore cylindrical. During the rotation of the rotor 12, the damping elements A, B lying loosely between the platforms 18 reach outward in the radial direction R and are pressed against the beveled undersides of adjacent platforms 18 by the centrifugal force. Each damping element A abuts against two blades 14 forming a blade pair a directly adjacent to one another. Also, each damping element B is located on two immediately be ^¬ adjacent to a pair of blades b forming blades fourteenth Due to the circular cross-section of the damping elements A, B, these are in each case to form a line contact on each blade 14 at. Since each blade 14 has a damping element A, B on both sides of the blade neck, each blade 14 belongs to both blade pairs a, b. According to the blade arrangement 11 shown in FIG

Group 24 of blade pairs a and a second group 26 of blade pairs b are provided, wherein each pair of blades a (or b) of the one group 24 (or 26) seen in the circumferential direction, of a blade pair b (or a) of the other group 26th (or 24) is adjacent. Due to this configuration, the

Damping elements A, B in the circumferential direction U alternately ^¬ lined up between two immediately adjacent blades 14. This embodiment is also referred to as an arrangement with an ABAB pattern.

In FIG 2 and the other figures, identical features are provided with the same reference numerals.

The embodiment according to FIG. 2 differs from the embodiment according to FIG. 1 only in the form and shape of the respectively second damping element. Instead of the damping elements B provided with a ^smaller diameter, damping elements B 'are now provided in FIG. 2, which in principle have the same diameter as the damping elements of type A, but the cross-sectional shape of the damping elements B' is not circular, but circular segment-shaped. The shape of the circle segment is chosen such that the center of the complete circle is still separated from the circle segment transverse. is enclosed. By the circular segment shape is damping element B 'on one (of each ^¬ right shown in Figure 2 weils) blade 14 of the blade pair of b and area of the other (the left as shown in FIG 2 each) blade 14 of the blade pair b' line-like at. According to the blade arrangement 11 shown in FIG. 2, a first group 24 of blade pairs a and a second group 26 of blade pairs b 'are thus provided, each of them

Blade pair a (or b ') of one group 24 (or 26) seen in the circumferential direction U, of a pair of blades b' (or a) of the other group 26 (or 24) is adjacent. Again, in principle, it is a row with an ABAB pattern, in which the specified order of the damping elements A, B 'and the blade pairs a, b' along the circumference U of the blade ring 10 is repeated in a regular order.

3 shows the detail of the development of the blade ring 10 with rotor blade 14 according to FIG. 2, wherein instead of the damping elements A and B ', the springs 28, 30 to be used in the replacement model of the damping ^elements A, B' are shown. Since the damping element A is a symmetrical or cylindrical damper, a translational spring 28 for coupling the two blades 14 of the blade pair a is shown in the replacement model. The asymmetrical Dämpfungsele ^¬ ment B 'forces due to the flat contact of the Kreisseh ^¬ nenabschnitts on the sloping underside of the platform 18 in addition to translation a moment, so that in addition to the translation spring 28, a torsion spring 30 in Ersatzschalt- image between the blades 14 of the blade pair b' is Darge ^¬ provides. The translational springs 28 have a coupling rigidity Cl, C3 and the torsion spring has a coupling stiffness C2. The entire coupling stiffness of a single blade 14 is then obtained by the parallel connection of the coupling stiffness C3 on the one hand and the coupling stiffnesses

C2 and Cl. The springs can thereby also have nonlinear individual ^¬ properties. Since the blades 22 are set in relation to the axial direction X and thus the two sides of the platform 18 of a blade 14 are designed asymmetrically laterally of the blade 22, the row with the ABAB pattern of damping elements A, B and A, B 'causes an alternating Frequency detuning of blades 14, whereby the natural frequencies of immediately adjacent blades 14 are shifted solely by the use of different damping elements A, B, B '. The shifting of the frequencies in operation prevents the propagation of circumferential oscillatory waves in the scooped rim, which makes it difficult to excite the blades 22 to flutter. This increases ^¬ ding the operating area of the axial turbomachine and ensures safe operation.

Further embodiments for detuning the natural frequencies of vibration modes of blades 14 are shown in FIG. 4, FIG. 5, FIG. 6 and FIG. In it, further rows with different patterns are given by way of example.

4 shows a new row with three groups 24, 26, 27 of blade pairs a, b, d, wherein each pair of blades a and b and d of a group 24 or 26 and 27 of two Schaufelpaa- ren b, d or A, D and A, B is adjacent, each one of the other two groups 26, 27 and 24, 27 and 24, 26 are associated. Between the two blades 14 of each pair of blades a is a damping element of the type A vorgese ^¬ hen. This is circular in cross-section and has a rather larger diameter. Each pair of blades b is assigned a damping element of the type B, which is also circular in cross-section. Compared to the type A damping ^element , the diameter of the type B damping ^element is smaller. Each pair of blades d is assigned a damping element of type D. In the illustrated embodiment, its configuration corresponds to the embodiment of the damping element of the type B 'of FIG 2. This embodiment therefore has an ABCABC series. According to FIG 5, a further vane assembly 11 is shown in which a first group 24 and a second group 26 of display ^¬ felpaaren a, b '' are provided, each blade pair a of the first group 24 of a blade pair a of the first group 24 and a blade pair b '' of the second group 26 is adjacent. Between the two blades 14 of each blade pair a, a damping element of the type A is provided. This is circular in cross-section and has a rather larger diameter. Each pair of blades b '' is associated with a damping element of the type B '', whose cross-section is a circular segment. This embodiment can be described as AABBAABB series. An alternative embodiment with an ABBABB series is shown schematically in FIG. Again, the different types A, A, B "of the damping elements are distributed along the circumference between the blades 14 of the blade ring 10 in a recurring order.

7 finally shows a further ABAB FIG series of abgeän ^¬ derten damping elements E, H in a rotor blade ring. A first group 24 of pairs of blades e 14 has, in each case, a damping element of type E between the respectively associated blades 14. Also, the damping element E is designed in principle rod-shaped. In contrast to the embodiments of damping elements A, B, B ', B ", D shown up to ^now, however, this is triangular in cross-section so that it rests flat on each blade 14 of the blade pair e associated therewith. The difference in the damping element E ^¬ H damping element is designed in several parts and in each case comprises two parts Hl, H2. The part H1 is triangular in cross-section and the part H2 has in cross section the contour of a circular sector in the form of a quadrant. This results in two surface contacts and one line contact per damping element H. The blade arrangements 11 shown in FIGS. 4, 5, 6 and 7 have higher coupling stiffnesses than the configurations according to FIG. 1 or FIG. 2, whereby mutually immediately adjacent blades 14 are even more clearly detuned in their frequency characteristics. In this respect, these are suitable

Blade assemblies 11 to be especially when using ^¬ Licher damping elements distinguished a frequency detuning of blades 14 of a blade ring 10 brought about in order to prevent the flutter excitation of the blades fourteenth

Depending on the number of blades 14 in the blade ring one of the aforementioned blade assemblies 11 is particularly applicable. Of course, it is possible, if the number of blades in the ring is not divisible by two or by three, to use a larger number of damping element types per blade ring 10.

If the blade ring 10 has a number of blades 14, which is not an integer multiple of the number of Dämp ^¬ tion element types of the series, it is of course possible for all Ausgestal ^¬ tions that only a majority of the successive blade pairs (a, b, b ' , b '', d, e, h) are members of the series and form them. The remaining pairs of blades are then provided with suitable damping elements that can not be subordinate to the row. In this case, there is also the possibility that the blade ring 10 actually has two adjacent blades 14 with identical or approximate frequency characteristics.

In addition, a wide variety of damping element types are possible and can be combined with each other so that the embodiments presented herein are standing ^¬ limiting to ver in any way as. Even alternating in circumferential direction at ^¬ order of damping elements of type B 'and type B''results due to the already mentioned above, varying of display ^¬ fel to blade stiffness coupling to an alternating frequency detuning. For example, it would be conceivable that grooves (grooved damping elements) along the cross-sectional contour are provided as a distinguishing feature between damping elements of different types. In addition, other rows of Dämpfungsele ^¬ ment types are also possible, for example, a ABCBABCBA- row.

Overall, the invention thus relates to a blade assembly 11 having a rotor 12 and a plurality of blades 14 distributed along the circumference U of the rotor 12 in a ring 10, wherein two immediately adjacent blades 14 of the ring 10 a blade pair a, b, b ', b' ' , d, e, h, between whose blades 14 a damping element A, B, B ', B' ', D, E, H is arranged and where by a force acting in the radial direction R centrifugal force upon rotation of the rotor 12th around a rotor axis, the respective damping element A, B, B ', B' ', D, E, H with the two blades 14 of the associated blade pair a, b, b', b '', d, e, h come into contact , To a frequency detuning of the vibration characteristics of

Shovels 14 cause, whereby a mechanical processing of the blade 22 is obsolete, is pre ^¬ beat that the blade ring 10 at least two blade ^¬ pairs a, b, b ', b'', d, e, h with different damping elements A , B, B ', B ", D, E, H.

Claims

claims 1. blade arrangement (11),  with a rotor (12) and a plurality of vanes (14) distributed along the circumference of the rotor (12) in a ring (10), each of which successively comprises a blade root (16), a platform (18) and an airfoil (22),  wherein two immediately adjacent blades (14) of the ring (10) form a blade pair (a, b, b ', b' ', d, e, h) and which at least one damping element (A, B, B', B '' , D, E, H) is assigned and which (s)  by a centrifugal force acting in the radial direction (R) upon rotation of the rotor (12) about one  Rotor axis the respective damping element (A, B, B ', B' ', D, E, H) with the platforms (18) of the two blades (14) of its associated blade pair (a, b, b', b '', d, e, h) come into contact,  characterized in that  for adjusting the natural frequencies of the blades (14) of the blade ring (10) at least two blade pairs (a, b, b ', b' ', d, e, h) with different damping elements (A, B, B', B '', D, E, H). 2. blade assembly (11) according to claim 1, wherein each blade (14) of the collar (10) has two blade ^¬ pair (a, b, b ', b'', d, e, h) is assigned as well as two or more groups (24, 26, 27) of blade pairs (a, b, b ', b'', d, e, h) are provided,  within which the damping elements (A, B, B ', B' ', D, E, H) are each identical and  their damping elements (A, B, B ', B' ', D, E, H) differ from group (24, 26, 27) to group (24, 26, 27). 3. blade assembly (11) according to claim 2, in which a first group (24) and a second group (26) of blade pairs (a, b or a, b 'or e, h) are provided, wherein a majority of the blade pairs (a or b, b' or e) or each vane pair (a or b, b 'or e) of the a group (24 or 26) in the circumferential direction (U) seen by two blade pairs (b, b 'and a or h) of the other group (26 or 24) is adjacent. 4. blade assembly (11) according to claim 2,  in which a first group (24) and a second group (26) of blade pairs (a, b '') are provided, wherein a majority of the blade pairs (a or b '') or each ^¬ of the blade pair (a or b '') of one group (24 and 26) by a pair of blades (a or b '') of one group ( 24 and 26) and a blade pair (b '' and a) of the other group (26 or 24) is adjacent. 5. blade assembly (11) according to claim 2, wherein a first group (24), a second group (26) and a third group (27) of blade pairs (a, b, d) are pre ^¬ see,  wherein a majority of the pairs of blades (a or b or d) or each blade pair of a group (24 or 26 or 27) of two blade pairs (b, d or a, d or a, b) is adjacent, the each one of the other two groups (26, 27 and 24, 27 and 24, 26) are associated. 6. blade assembly (11) according to one of the preceding  Claims,  in which the different damping elements (A, B, B ', B' ', D, E, H) with respect to the size, the mass, the cross-sectional contour, the material and / or the nature of the coupling contact to the blades (14) out differ. 7. Blade assembly (11) according to one of the preceding  Claims,  in which the damping element (H) of a blade pair (h) is designed in several parts. 8. Gas turbine with a blade arrangement 11 according to one of claims 1 to 7.