The present invention relates to a rotor blade support structure and, to be more specific, relates to a rotor blade support structure wherein stress concentration in a rotor blade groove in which a rotor blade is embedded is reduced.
Industrial turbines and steam turbines each include a casing and a rotor rotatably supported by the casing. The turbine has a structure in which rotor discs are installed in the rotor in multiple stages in a rotor axial direction and rotor blades are embedded respectively in multiple rotor blade grooves provided in a peripheral surface of each rotor disc.
Here, description is given of the rotor blade groove with reference to
In the turbine described above, a temperature difference between the inside and the outside of the rotor disc increases in, for example, startup and shutdown. Thus, stress concentration occurs due to transient thermal stress near the circumferential groove portion of the rotor blade groove. For example, through a simulation of a stress concentration coefficient in a rotor disc having rotor blade grooves with the aforementioned shape, we have confirmed that, as shown in
The present invention has been made to solve the problems described above and an object thereof is to provide a rotor blade support structure wherein stress concentration near a rotor blade groove in which a rotor blade is embedded is suppressed with an increase in manufacturing cost also being suppressed.
A rotor blade support structure of the present invention which solves the problems described above is a rotor blade support structure in which a rotor blade is embedded in a rotor blade groove provided in a rotor disc, characterized in that the rotor blade groove includes:
a circumferential groove portion in a bottom portion of the rotor blade groove, the circumferential groove portion extending in a rotor disc circumferential direction beyond a portion above the bottom portion; and
an axial groove portion which is provided in a center portion of the bottom portion in the rotor disc circumferential direction, in an end surface portion of the rotor disc and extends in a rotor disc axial direction.
A rotor blade support structure of the present invention which solves the problems described above is the aforementioned rotor blade support structure of the present invention characterized in that w′/W is within a range of 0.49 to 1.0, where 2W represents a size of the bottom portion of the rotor blade groove in the rotor disc circumferential direction and 2w′ represents the size of the axial groove portion in the rotor disc circumferential direction.
A rotor blade support structure of the present invention which solves the problems described above is the aforementioned rotor blade support structure of the present invention characterized in that an angle with respect to the bottom portion of the rotor blade groove in the axial groove portion is within a range of 20° to 50°.
A rotor blade support structure of the present invention which solves the problems described above is the aforementioned rotor blade support structure of the present invention characterized in that d/w′ is within a range of 1.0 to 1.4, where d represents a size of the axial groove portion in the rotor disc axial direction.
In the rotor blade support structure of the present invention, the axial groove portion is provided in the center portion of the bottom portion of the rotor blade groove in the rotor disc circumferential direction, in the end surface portion of the rotor disc. This causes the stress concentration coefficient to be distributed to the circumferential groove portions and the axial groove portion in the rotor blade groove when transient thermal stress occurs. As a result, stress concentration in the circumferential groove portion in the rotor blade groove is suppressed. There is a need to only provide the axial groove portion in the rotor blade groove and an increase in manufacturing cost is thus suppressed.
With reference to
As shown in
Each rotor blade groove 10 penetrates one end surface portion 1b of the rotor disc 1 and the other end surface portion 1a opposite to the one end surface portion 1b and extends in a direction inclined with respect to a circumferential direction of the rotor disc 1. The rotor blade groove 10 has a shape including a groove portion 11 along the platform 32 of the rotor blade 30 and a groove portion 12 along the blade root 31 of the rotor blade 30. The rotor blade groove 10 includes circumferential groove portions 13, 13 in a bottom portion 14 of the rotor blade groove 10 which have arc-shaped ends and which extend in the rotor disc circumferential direction beyond a portion above the bottom portion 14.
The rotor blade groove 10 described above further includes an axial groove portion (relief groove portion) 15 formed in a center portion of a bottom portion 14 in the rotor disc circumferential direction in each of the end surface portions 1a, 1b of the rotor disc 1. The axial groove portion 15 extends in an axial direction of the rotor disc 1 and has an arc-shaped end. Providing the axial groove portion 15 as described above has the following effect. Tensile stress in the rotor disc circumferential direction is generated in layers in the rotor disc 1 by transient thermal stress and a flow of the stress in the rotor disc circumferential direction which conventionally concentrates in the circumferential groove portion of the rotor blade groove is distributed to the circumferential groove portions 13, 13 and the axial groove portion 15 of the rotor blade groove 10 and is alleviated. Thus, the stress concentration in the circumferential groove portions 13, 13 in the rotor blade groove 10 can be suppressed. As shown in
Here, with reference to
As shown in
It is thus confirmed that the stress generated by the transient thermal stress can be distributed to the circumferential groove portions 13, 13 and the axial groove portion 15 of the rotor blade groove 10 and be alleviated when the size of the axial groove portion 15 with respect to the rotor blade groove 10 (w′/W) is set within a range of 0.49 to 1.0.
With reference to
As shown in
It is thus confirmed that the stress generated by the transient thermal stress can be distributed to the circumferential groove portions 13, 13 and the axial groove portion 15 of the rotor blade groove 10 and be alleviated when the degree of the relief angle in the axial groove portion 15 is set within a range of 30.0° to 50.0°.
With reference to
As shown in
It is thus confirmed that the stress generated by the transient thermal stress can be distributed to the circumferential groove portions 13, 13 and the axial groove portion 15 of the rotor blade groove 10 and be alleviated when the size of the axial groove portion 15 in the axial direction with respect to the size thereof in the rotor disc circumferential direction (d/w′) is set in a range of 1.0 to 1.4.
Here, with reference to
As shown in
Thus, the flow of the stress in the rotor disc circumferential direction which conventionally concentrates in the circumferential groove portion of the rotor blade groove can be distributed to the circumferential groove portions 13, 13 and the axial groove portion 15 of the rotor blade groove 10 and be alleviated by providing the axial groove portion 15 in the rotor blade groove 10.
As described above, in the rotor blade support structure of the embodiment, the axial groove portion 15 is provided in the center portion of the bottom portion 14 of the rotor blade groove 10 in the rotor disc circumferential direction, in each of the end surface portions 1a, 1b of the rotor disc 1 in the rotor blade groove 10 and this has the following effects. The tensile stress in the rotor disc circumferential direction is generated in layers in the rotor disc 1 by the transient thermal stress and the flow of the stress in the rotor circumferential direction which conventionally concentrates in the circumferential groove portion of the rotor blade groove can be distributed to the circumferential groove portions 13, 13 and the axial groove portion 15 of the rotor blade groove 10 and be alleviated. Thus, the stress concentration in the circumferential groove portions 13, 13 in the rotor blade groove 10 is suppressed. Moreover, there is a need to only provide the axial groove portion 15 in the rotor blade groove 10. Since the axial groove portion 15 can be easily formed by machining and there is no need to change the shapes of the circumferential groove portions in the rotor blade groove, an increase in manufacturing cost can be suppressed. Furthermore, the axial groove portion can be provided in the rotor blade groove of the rotor disc not only in a case of newly installing a turbine but also in maintenance.
The present invention is the blade support structure and can suppress the stress concentration in the circumferential groove portion in the rotor blade groove in which the rotor blade is embedded, with an increase in manufacturing cost suppressed. Accordingly, the present invention can be used beneficially in the power generating industry which uses tribunes.
Number | Date | Country | Kind |
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2011-230293 | Oct 2011 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2012/076650 | 10/16/2012 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2013/058220 | 4/25/2013 | WO | A |
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Number | Date | Country | |
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20140219806 A1 | Aug 2014 | US |