JP2015509161A - Rotor for turbomachine - Google Patents

Abstract

The present invention relates to a rotor for a double-flow turbomachine, wherein the first flow and the second flow have a plurality of blade rows, at least one blade row corresponding to a corresponding blade row of the other flow. Have been implemented differently.

Description

  The present invention relates to a rotor for a double flow turbomachine, in particular a steam turbine, the rotor having a first rotor part for a first flow and a second rotor part for a second flow. And the first rotor portion has a first blade row, a second blade row, a further blade row, and a last blade row, the second rotor portion being a first rotor row. , A second blade row, a further blade row, and a last blade row.

  For example, a turbomachine, such as a steam turbine, generally includes a rotor that is rotatably supported and a housing that is provided around the rotor. There is a danger that a constant torsional frequency can cause the rotor or the blades provided on the rotor to break. Accordingly, it is known that a rotor for a turbomachine is designed in a range of a constant operating frequency where no torsional frequency is generated, and a moving blade provided on the rotor affects the torsional frequency.

  The object of the present invention is to describe a rotor for a turbomachine that has a relatively low tendency to torsional frequency.

  The above problem is a rotor for a double flow turbomachine, in particular a steam turbine, the rotor comprising a first rotor part for a first flow, a second rotor part for a second flow, The first rotor portion has a first blade row, a second blade row, a further blade row, and a last blade row, the second rotor portion Is solved by a rotor having a first blade row, a second blade row, a further blade row, and a last blade row. In the rotor, the configuration of the moving blades of the moving blade row of the first rotor portion is different from the moving blades of the moving blade row of the second rotor portion, The blades of the corresponding blade rows of the second rotor portion are implemented substantially equally.

  According to the present invention, in a rotor implemented in a double flow manner, a moving blade row in the first flow and a corresponding moving blade row belonging to the moving blade row of the first flow in the second flow are identical to each other. It is based on the idea that it is implemented. The rotor typically has a first blade row in both the first flow and the second flow, and the blade rows are implemented identically. The moving blades of the second moving blade row in the first flow and the second flow are similarly implemented. These blade rows in the first flow and the second flow are blade rows that coincide with each other in the sense that the blade row changes the thermodynamic value of the flow medium substantially the same.

  Here, the present invention is based on the idea that it is not always necessary to implement the corresponding moving blade rows in the same manner. The present invention is rather based on the idea of forming the first flow and the second flow consciously different. For this purpose, the present invention proposes that the configuration of the moving blades of the moving blade row of the first rotor portion is different from the moving blades of the moving blade row of the second rotor portion. The proposal means that the corresponding blade rows are implemented differently from each other, and the remaining corresponding blade rows are performed substantially equally.

  Further advantageous developments are described in the dependent claims.

  Thus, in a first advantageous development, the last blade row of the first rotor part is formed differently than the last blade row of the second rotor part. . The blade length of the last blade row is maximal in both the first and second flow for thermodynamic reasons. Therefore, the last blade row has the greatest influence on the torsional vibration of the rotor. Therefore, changing the blade row has a great influence on the entire rotor.

  In an advantageous development, the blades of the different blade rows are different with regard to the dynamic properties of the blades.

  In a further advantageous development, the blades of the different blade rows are different with respect to the elastic properties of the blades. In addition to mechanical properties, the elastic properties of the blades play an important role in influencing torsional vibrations in the rotor. Therefore, changing the dynamic characteristics and / or elastic characteristics of the moving blade has a great effect on torsional vibration.

  In a further advantageous development, the blades of the different blade rows are different with respect to the outer geometry of the blades.

  Also in an advantageous development configuration, the blades of the different blade rows are implemented differently with respect to the material of the blades. Rotor blades implemented differently in geometry have different frequency spectra, so that a blade row implemented differently in geometry affects the torsional vibration of the rotor. The density of the materials used and the further physical properties have a great influence on the torsional vibration.

  In an advantageous development configuration, the individual blades are implemented differently. It is likewise possible to change a plurality of individual blades in one blade row or in different blade rows, thereby realizing torsional vibration changes.

  In a further advantageous development, the plurality of blade rows of the first rotor part are implemented differently with respect to the blade row of the second part. Depending on what torsional vibration is expected or to be damped, the blades of different blade rows can be implemented differently.

  Here, the present invention will be described in more detail based on the embodiments.

It is the figure which showed roughly the cross section of the rotor which concerns on this invention.

  FIG. 1 shows a cross section of a rotor 2 that is rotatably supported around a rotating shaft 1. The rotor 2 is characterized by a diameter 3 and a rotor blade is provided on the surface 4 of the rotor 2. The illustrated rotor 2 includes a first rotor portion 5 for a first flow. The first rotor part 5 includes a first blade row 7, a second blade row 8 and a last blade row 9. Additional blade rows are not drawn for reasons of clarity.

  Similarly, the second rotor portion 6 includes a first blade row 10, a second blade row 11, and a last blade row 12 corresponding to the first blade row 7 of the first flow path 14. Is included. The first moving blade row 7 and the moving blade row 10 are moving blade rows corresponding to each other. This means that according to the prior art, these two blade cascades have a substantially equal configuration. Accordingly, the second moving blade row 8 and the second moving blade row 11 are also the corresponding moving blade rows. The same applies to the last moving blade row 9 and the last moving blade row 12. That is, the two moving blade rows are moving blade rows corresponding to each other. Each moving blade row includes a plurality of moving blades, and the plurality of moving blades are provided on the outer periphery of the rotor 2.

  The configuration of the blades of the last blade row 9 is implemented according to the invention differently from the configuration of the blades of the last blade row 12 of the second rotor part 6. Since the configuration of the moving blades in the moving blade row 9 is different from that of the moving blades in the moving blade row 12, the entire frequency characteristics of the rotor 2 are substantially the same as each other. The frequency characteristics are different.

  The remaining moving blade row, that is, the first moving blade row 7 is substantially the same corresponding to the moving blade row 10.

  During operation, fresh steam flows into the inflow region 13 via an inflow not shown in detail, from which the first flow path in the first rotor part 5 of the first flow, and the second And the second flow path 15 in the second rotor portion 6 in the flow.

  The moving blades of the last moving blade row 9 are implemented differently with respect to the moving blades of the last moving blade row 12 with respect to the mechanical and / or elastic properties of the moving blade. To this end, the blades of the different blade rows are implemented differently with respect to the outer geometry and / or material of the blades.

  By changing the configuration of the moving blades in the moving blade row as in the present invention, an additional degree of freedom for changing the torsional frequency in the rotor 2 can be obtained.

DESCRIPTION OF SYMBOLS 1 Rotating shaft 2 Rotor 3 Diameter 4 Surface 5 First rotor part 6 Second rotor part 7 First moving blade row 8 Second moving blade row 9 Last moving blade row 10 First moving blade row 11 First Second moving blade row 12 Last moving blade row 13 Inflow region 14 First flow path 15 Second flow path

Claims (8)

A rotor (2) for a double-flow turbomachine, in particular a steam turbine,
The rotor (2) has a first rotor part (5) for a first flow and a second rotor part (6) for a second flow;
Said first rotor part (5) comprises a first blade row (7), a second blade row (8), a further blade row and a last blade row (9);
Said second rotor part (6) has a first blade row (10), a second blade row (11), a further blade row and a last blade row (12);
The configuration of the moving blade row (7, 8, 9) of the first rotor portion is different from the moving blade row (10, 11, 12) of the second rotor portion. Has been implemented as
The rotor (2), wherein the blades of the corresponding blade rows of the first rotor portion and the second rotor portion are substantially equally implemented.   The blades of the last blade row (9) of the first rotor portion (5) are in relation to the blades of the last blade row (12) of the second rotor portion (6). The rotor (2) according to claim 1, wherein the rotor (2) is implemented differently.   The rotor (2) according to claim 1 or 2, wherein the blades of different blade rows differ with respect to the mechanical properties of the blades.   The rotor (2) according to any one of the preceding claims, wherein the blades of the different blade rows are different with respect to the elastic properties of the blades.   The rotor (2) according to any one of the preceding claims, wherein the blades of the different blade rows are different with respect to the outer geometry of the blades.   The rotor (2) according to any one of the preceding claims, wherein the blades of the different blade rows are different in terms of material.   The rotor (2) according to any one of the preceding claims, wherein the individual blades are implemented differently in the blade row of the blades.   The plurality of blade rows of the first rotor part (5) are implemented differently with respect to the blade row of the second rotor part (6). The rotor (2) described in 1.

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