EP1574666A1 - Turbine blade array - Google Patents

Abstract

The turbine blade row has the blades (19,19',20,20') divided into at least two groups which differ in a mechanical inherent frequency of the blades allocated to them. The turbine blades are divided into a number of spatially adjoining blocks (28',29',30'), whereby the turbine blades of each block stem from different groups. A group with regard to its inherent frequency is determined by a selection of its sheet thickness. An independent claim is included for a turbine engine with a row of blades as specified in the invention.

Description

The invention relates to a turbine blade row with a Number of turbine blades and a turbomachine, having such a turbine blade row.

A turbomachine, in particular a steam turbine, has substantially moving parts and stationary parts. The moving parts include a rotatably mounted about a rotation axis rotor. The rotor is usually housed in an inner housing. The inner housing is attached within some outer embodiments of a steam turbine in some embodiments. The rotor has a rotor shell surface, are mounted on the symmetrical to the axis of rotation in the radial direction extending blades.
A blade row consists of blades which are mounted in a common plane perpendicular to the axis of rotation on the rotor.

On the inner housing are several consisting of vanes Guide vane rows attached. The vane rows differ among other things by the length of the individual vanes.

The inner housing and the rotor are formed in such a way that between the rows of vanes, the blade rows protrude. A guide or blade is also called Turbine blade called. Likewise, a Leit- Blade row also known as turbine blade row. A flow medium, in particular water vapor, flows over an entrance to the steam turbine and is through the deflected individual runners and vanes. The temperature the flow medium drops here. It finds one Energy conversion of initially thermal energy in kinetic energy instead. As a result of this energy conversion the rotor is set in a rotary motion. These Rotational motion can generate electrical energy used by means of a generator connected to the rotor become.

Usually, steam turbines depending on the pressure and Temperature range in high pressure, medium pressure and Divided into low pressure steam turbines. In low-pressure turbines the volume flows of the flow medium are proportionate large. A low pressure steam turbine is by relative long runners and guide vanes marked.

In high-pressure and medium-pressure steam turbines, the and blades usually solid. Steam turbines are usually for speeds of 50 or 60 Hz. Constructed. Converted at these speeds 3000 revolutions / min or 3600 revolutions / min occur enormous Centrifugal forces in the blades. The blades of a Low-pressure steam turbine are therefore made hollow to the Weight of the blades to a minimum. In addition, a hollow running blade cheaper than a solid running blade. In addition to the blades are also the vanes usually hollow at least in low-pressure steam turbines executed.

The hollow guide and blades are made a sheet metal or two deep-drawn Sheet metal halves welded together. Disadvantageous in operation a steam turbine are vibrations of the leading and Blades. The natural frequencies of hollow formed Guides and blades are compared to massive ones Lower vanes.

Disadvantage of a hollow guide or blade is due to the relatively low natural frequencies, the Tendency to a so-called flutter. Under fluttering becomes an aerodynamic excitation with the natural frequency of the running or vanes understood. A too strong flutter can lead to a failure of the steam turbine in total.

To avoid vibrations of the guide vanes and blades These were previously made of stiff material educated.

The object of the present invention is to provide a To introduce turbine blade row, the small invalid Has vibrations.

The task is performed by a turbine blade row with a Number of turbine blades solved, the Turbine blades are divided into at least two groups, which is in a mechanical natural frequency of them different turbine blades.

The inventors have recognized that in addition to the suggestion for Flutter of individual guide or blade, another Fluttering phenomenon occurs when adjacent Leit- Blades similar or same natural frequencies exhibit. This leads to resonance-like amplified Vibrations, which also cause a failure of the whole Steam turbine could lead.

The turbine blade row is not according to the invention formed throughout with identical turbine blades. Rather, at least two groups of consciously become aware Turbine blades formed. The mechanical natural frequency a turbine blade in a group is different from the mechanical natural frequency of a turbine blade one other group. A forced oscillation of a Turbine blade from a group has a lower Influence on the vibration of a turbine blade from a other group than the vibration of a turbine blade from the same group. A mutual suggestion of Turbine blades from different groups is thereby minimized as far as possible.

It is particularly advantageous if the turbine blade row in a number of spatially contiguous blocks divided, with the turbine blades of each block come from different groups. This will be a mutual Excitation of the turbine blades even further diminished because of spatial distance between two turbine blades different groups is particularly low.

Another advantage arises when the order of Turbine blades inside the blocks in terms of their Group affiliation is consistent.

This will result in an arrangement of the turbine blades presented, which shows a high degree of symmetry. With Model calculations can be used to determine which vibrations the turbine blades are to be expected during operation. By the Arrangement of the turbine blades in a particular Order creates a possibility, close beside a turbine blade from a group always a suitable To arrange turbine blade from another group. In addition, a mutual suggestion about the Turbine blades reduced overall.

In an advantageous development, a group in terms of their natural frequency by a selection of their Material thickness determined. This will be a cost effective and comparatively easy way Turbine blades with different natural frequencies too create.

Conveniently, the turbine blade row in a Turbomachine used. In particular, the Turbine blade row in gas or steam turbines, in Compressors used in pumps or in blowers.

Embodiments of the invention are described below Referring to the drawings described in more detail. Have along Components provided with the same reference numerals are the same Functionality.

Fig. 1

ein Schnittbild einer Dampfturbine;

Fig. 2

eine Draufsicht auf eine Turbinenschaufelreihe;

Fig. 3

eine schematische Darstellung einer Turbinenschaufel;

Fig. 4

eine schematische Darstellung einer Turbinenschaufelreihe;

Fig. 5

eine schematische Darstellung einer Turbinenschaufelreihe.

Showing:

Fig. 1

a sectional view of a steam turbine;

Fig. 2

a plan view of a turbine blade row;

Fig. 3

a schematic representation of a turbine blade;

Fig. 4

a schematic representation of a turbine blade row;

Fig. 5

a schematic representation of a turbine blade row.

In Figure 1 is a sectional view through a steam turbine 1 as Embodiment of a turbomachine shown. The Steam turbine 1 has a rotor 2 with a rotor surface on, in a manner not shown to a Rotation axis 3 is rotatably mounted. The steam turbine 1 has an inner housing 4, which is rotationally symmetrical to Rotation axis 3 is arranged. The rotor 2 has radial extending blades 5, which in a circumferential direction rotationally symmetrical to the axis of rotation 3 on the Rotor surface to a blade row (17) mounted one behind the other. In the in Figure 1 shown steam turbine 1 is shown by the sectional view only one blade 5 per row of blades (17) detect. In the direction of the axis of rotation 3 are depending on Embodiment of the steam turbine 1 a certain number Turbine blade rows formed.

On an inner surface of the inner housing 4 are guide vanes 6th appropriate. Multiple vanes 6 are rotationally symmetrical to the axis of rotation 3 on the inner housing. 4 appropriate.

A flow medium, in particular steam, flows over one Inflow 8 in the steam turbine. The Flow medium flows alternately along the axis of rotation through a guide or blade row. The thermal Energy of the flow medium is here in kinetic Energy converted. The rotor 3 is thereby in rotation added.

The flow medium then flows out of a Outflow region 9 from the steam turbine.

FIG. 2 is a plan view of a blade row 17 to see. The blades 5 are in a direction of rotation 11 arranged at equidistant intervals on the rotor 2.

In Figure 3, a blade 5 can be seen. The blade 5 becomes from a direction 12 of a flow medium incident flow. The blade 5 is hollow and has a pressure side 13 and a suction side 14. The Flow medium first flows to a leading edge 15 and then flows to a trailing edge 16. The blade 5 moves in operation about the axis of rotation. 3

FIG. 4 shows a developed turbine blade row 17 shown. The turbine blade row 17 may consist of Leit- or Blades exist.

The turbine blade row 17 has a first one Natural frequency having first turbine blade 19. to first turbine blade 19 directly adjacent is a second natural frequency having second turbine blade 20th arranged. The first and second natural frequency is differently. The first turbine blade 19 is here hollow executed and from a sheet with a certain first sheet thickness formed. The second turbine blade 20 is also made hollow and from a second sheet formed with a second sheet thickness. By choosing the Sheet thickness can be formed arbitrary natural frequencies become. In addition to the second turbine blade 20 is a a third natural frequency third turbine blade 25 arranged. The third turbine blade 25 is as well as the first 19 and second turbine blade 20 made hollow. In addition to the third turbine blade 25 is another one Natural frequency having further turbine blade 26th arranged. Of course, the turbine blades 19, 20, 25, 26 also alternately solid and hollow or only massive be executed.

With the arrangement of an additional natural frequency having additional turbine blade 27 is Finally, a first block 28 formed from a predetermined number of by their natural frequency distinguishable turbine blades 19, 20, 25, 26, 27 is trained. In that shown in Figure 4 Embodiment, the first block 28 five Turbine blades 19, 20, 25, 26, 27 on.

The turbine blades 19, 20, 25, 26, 27 are in this Embodiment divided into five groups, where the groups in a mechanical natural frequency of them associated turbine blades 19, 20, 25, 26, 27 differ.

In the embodiment shown in Figure 4 is the Order within blocks 28, 29, 30 in terms Consistent with their group affiliation.

Also conceivable is any order of Turbine blades 19, 20, 25, 26, 27 in the blocks.

But a block can also have fewer turbine blades 19, 20, 25, 26, 27.

In addition to the first block 28, a second block 29 arranged. The second block 29 has the same number Turbine blades 19, 20, 25, 26, 27, as the first block 28. The order and natural frequencies of the turbine blades 19, 20, 25, 26, 27 of the first block 28 and the second Block 29 are identical here. At the second block 29 a further block 30 is arranged. The further block 30 has as many turbine blades as the first Block 28 and the second block 29 and is what the order the turbine blades 19, 20, 25, 26, 27 and the Natural frequencies are identical to these. A Turbine blade row 17 is finally formed, the a predetermined number of blocks 28, 29, 30 has. The Number of blocks 28, 29, 30 depends on the size of the Turbine blades 19, 20, 25, 26, 27 and of the diameter of the rotor 2 from.

The blocks 28, 29, 30 are formed such that the Turbine blades 19, 20, 25, 26, 27 of each block 28, 29, 30th come from different groups.

The embodiment of a turbine blade row 17 in Figure 5 has a first natural frequency having first Turbine blade 19 'and a second natural frequency having second turbine blade 20 'on. The first Turbine blade 19 'and the second turbine blade 20' together form a first block 28 '. A second block 29 'is right next to the first block 28. Next to the second Block 29 'is in turn a further block 30' attached, the a first turbine blade 19 'and a second one Turbine blade 20 'has. At this further block 30 ' There are additional blocks, which consist of a first turbine blade 19 and a second turbine blade 20 exist. The number at blocks 28 ', 29', 30 'depends on the size of the Turbine blades 19 ', 20' and the diameter of the rotor 2 off.

Claims (5)

Turbine blade row (17) with a number of turbine blades (19, 19 ', 20, 20', 25, 26, 27)
characterized in that
the turbine blades (19, 19 ', 20, 20', 25, 26, 27) are divided into at least two groups, which are in a mechanical natural frequency of their associated turbine blades (19, 19 ', 20, 20', 25, 26 , 27) differ. Turbine blade row (17) according to claim 1,
characterized in that
the turbine blade row (17) is divided into a number of spatially adjoining blocks (28, 28 ', 29, 29', 30, 30 '), the turbine blades (19, 19', 20, 20 ', 25, 26, 27 ) of each block (28, 28 ', 29, 29', 30, 30 ') originate from different groups. Turbine blade row (17) according to 2,
characterized in that
an order of the turbine blades (19, 19 ', 20, 20', 25, 26, 27) within the blocks (28, 28 ', 29, 29', 30, 30 ') is constant in terms of group membership. Turbine blade row (17) according to one of claims 1 to 3,
characterized in that
a group is determined in terms of their natural frequencies by a selection of their sheet thickness. Turbomachine with a turbine blade row (17) according to one of claims 1 to 4.

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