EP1860280A1 - Locking device of a turbine blade with a locking element - Google Patents

Abstract

The turbine has a turbine rotor (10) and a blade with a blade base (18) that is engaged with the rotor by groove/base connections and a blocking unit (16), where blocking recesses (20, 22) for accommodation of the blocking unit are provided in the base and the rotor, respectively. The blocking unit blocks the relative movement between the base and the rotor in an axial direction of the rotor under shear stress. The recesses are formed as a radial projection with a section having a circular segment and have a contact surface running transverse to the axial direction.

Description

The invention relates to a turbine for a thermal power plant comprising a rotor, at least one blade having a blade root engaging with the rotor via a groove / land connection, and a blocking element for blocking a relative movement between the blade root and the rotor in the axial direction of the rotor.

The turbine blades of turbines known in the art are often mounted axially on the turbine rotor. In this case, the blade roots are to be secured radially and axially in their rotor grooves in order to hold the blade in the rotor groove and to prevent a shaking movement of the same during turning operation of the turbine. Such a shaking movement leads to surface damage in the support flanks of the blade roots and their Nutzahntragflanken. This in turn leads to a shortened fatigue life of the affected components.

At the moment blade roots are e.g. secured by locking plates at the inlet and / or outlet of the blade roots axially in the corresponding rotor grooves. It is also known to use tangentially arranged, partially flattened and secured by the neighboring blade pins for axial locking. Furthermore, in previously known turbines and bent elements are used for axial securing, which absorb the transmitted axial force by bending. However, large axial forces between the turbine blade and the rotor can not be absorbed by such bending elements.

An object of the invention is to provide a turbine of the type mentioned, in which the securing of the blade in the axial direction relative to the turbine rotor is designed for receiving large axial forces.

This object is achieved according to the invention with a generic turbine, wherein in the blade root and the rotor is provided in each case a locking recess for receiving the blocking element such that the blocking element blocks a relative movement between the blade root and the rotor in the axial direction of the rotor under shear stress. The locking recesses in the blade root and the rotor are thus designed to receive the blocking element in the axial direction of the rotor such that an axial relative movement between the blade root and the rotor would cause a shear stress of the blocking element. In shear, a force directed parallel to an upper surface of a body acts on an upper portion of the body. If its base can not move, the upper surface of the same is moved relative to the base. Relative to the blocking element according to the invention, a shear stress means that one of the blocking recesses of the blade root and the rotor exerts a force parallel to this upper surface on the blocking element in an upper region of the blocking element, while the other blocking recess holds the base surface or a lower region of the blocking element ,

The shearing stress of the blocking element according to the invention makes it possible to absorb large axial forces between the blade root and the turbine rotor with a relatively small element. Furthermore, the axial securing can be realized with minimal parts expenditure and furthermore low demands on the precision of the required components and the recesses or grooves to be introduced into the rotor and the blade. Since the solution according to the invention is not a closing bucket solution, ie the same for all buckets of the series, it is possible to specifically remove and install individual buckets during service measures. Furthermore, no risk of cracking grooves must be provided in the inventive solution. Rather, the locking recess can be kept relatively flat in the rotor. In the prior art partially required deep cutouts in the rotor can be avoided. In addition, the inventive allows Solution a very cost-effective axial securing a blade root on the rotor.

Advantageously, the locking recesses in the blade root and the rotor are designed to receive the blocking element in a form-fitting manner at least in the axial direction of the rotor. This means that the blocking element is inserted in the axial direction in both the locking recess of the blade root and the locking recess of the rotor accurately, so that the locking element is held both by the locking recess of the blade root and the locking recess of the rotor in the axial direction. By means of this embodiment according to the invention it is achieved that the blade root is fixed with respect to the turbine rotor almost free of play in the axial direction, which increases the durability of the connection.

Expediently, the respective locking recess in the blade root and / or the rotor is designed as a radial depression with a profile, in particular having a circular segment. Advantageously, the profile of the recess is adapted to receive a circular locking element in a locking position for blocking an axial relative movement between the blade root and the rotor.

In order to make the mounting of the blade root in the turbine rotor as simple as possible, it is expedient if the blocking element in the respective locking recess in the blade root and / or the rotor from a blade mounting position for mounting or dismounting of the blade root in a blocking position for blocking a in the axial direction the rotor takes place relative movement between the blade root and the rotor is displaceable. Advantageously, the locking recesses are each designed with respect to the rotor as radial depressions, which have an elongated shape in a direction perpendicular to the radial extent. Advantageously, the respective longitudinal extension of the locking recesses is directed transversely to the axial direction of the rotor. In particular, the respective direction of the longitudinal extent concludes the Sperrausnehmungen with the axial direction of extension of the rotor an angle of about 70 °. Conveniently, the locking recesses at the ends of their longitudinal extent each have semicircular profiles for receiving a circular locking element in the two extreme positions, wherein the longitudinal sides of the locking recesses are designed to be rectilinear.

In order to effectively block a relative movement between the blade root and the rotor in the axial direction of the rotor under shear stress of the blocking element, it is expedient for the respective blocking recess in the blade root and / or the rotor to have a contact surface extending transversely to the axial direction of the rotor.

In an expedient embodiment, the blade root and / or the rotor has a locking recess extending in the axial direction of the rotor, in particular a locking groove, and a locking member guided in the locking recess. The locking member is adapted for displacing the locking element into a locking position in the locking recesses of the blade root and the rotor, wherein the blocking element in the blocking position blocks a relative movement between the blade root and the rotor in the axial direction of the rotor. In particular, the locking member is adapted to move the locking member from a blade mounting position for mounting or dismounting the blade root on the rotor in the locking position. In this case, the blocking element is displaced in particular in the tangential direction with respect to the rotor. By means of the locking recess according to the invention, the blade root can easily be mounted and dismounted on the rotor and thereupon the axial locking can be produced or released without difficulty by means of the blocking element. In particular, the locking member is further configured to hold the locking member in the locked position.

Advantageously, the locking member is designed as a wedge piece. Thus, the locking member during insertion of the same in the locking recess continuously moves the locking element in the direction of the locking position. If the locking element designed as a wedge piece is then inserted sufficiently far into the locking recess, the locking element is in the intended locking position. In an alternative embodiment, the locking element is moved by means of a dedicated tool, such as a mandrel, in the locked position.

In a particularly advantageous embodiment, the locking member is rod-shaped, in particular designed as a wave wedge. Advantageously, the wave wedge has along its longitudinal extent wave-shaped deviations in the radial direction with respect to the turbine rotor, in particular in such a way that a chain of leaf springs results (1 to n leaf springs). When inserting the shaft key in the locking recess, the waves are pressed flat elastic. The elastically flattened waves counteract slipping out of the wave wedge. Advantageously, the locking member is designed as a curved wedge bar with waves, wherein the bending of the locking member is adapted to a possibly provided curved shape of the groove / web connection between the rotor and the blade root.

In addition, the locking member is bendable at its ends for securing against axial displacement of itself. In particular, the locking member after insertion into the locking recess can be bent at its ends, preferably with respect to the turbine rotor radially inwardly and is thereby secured against axial displacement. Advantageously, provided on the end faces of the rotor, in particular radially with respect to the rotor extending grooves for receiving the bent ends of the locking member. This reduces the erosion susceptibility of the bent ends. Since the axial securing of the blade according to the invention achieved over the shear piece is, must be secured by the bending of the locking member ends only the locking member against axial displacement. For this function, it is sufficient if the ends of the locking member are relatively thin, since the required securing force is small. The bending of the relatively thin ends can be carried out without problems in terms of assembly. All recesses in the blade root are in low-stress areas. Advantageously, the thickness of the locking member can be selected as low as possible and the blocking element can be arranged as close as possible to the outlet of the locking member from the rotor shaft.

In an advantageous embodiment, the blade root and / or the rotor shaft has an unlocking recess, in particular a bore and / or a groove, which is designed to receive an unlocking tool, in particular a pin punch for pushing out the blocking element from a blocking position in the locking recesses of the blade root and the rotor , In this blocking position, the blocking element blocks a relative movement between the blade root and the rotor in the axial direction of the rotor. Advantageously, the blocking element can be moved by means of the unlocking tool from the blocking position into a blade mounting position for mounting or demounting the blade root. In this position of the locking element, the blade root can be removed from the rotor by a substantially axial displacement.

Advantageously, the Entriegelungsaussparung runs in a low-stress region of the blade root. To disassemble a blade root, the ends of the locking member are first bent back and removed the same by expulsion. About the Entriegelungsaussparung in low-stressed area of the blade root is then pushed with a flattened pin punch the locking element in the blade mounting position. Now the shovel can be like slide over the locking element during installation and remove it along the groove / web connection.

Fig. 1

eine perspektivische Ansicht eines Turbinenrotorabschnitts mit einer Schaufelbefestigungsnut,

Fig. 2a

eine Axialschnittansicht des Turbinenrotors gemäß Fig. 1 mit einem darin eingeführten Schaufelfuß sowie einem in einer Montageposition befindlichen Sperrelement,

Fig. 2b

die Schnittansicht des Turbinenrotors gemäß Fig. 2a bei der das Sperrelement in eine Sperrposition verschoben ist, sowie

Fig. 3

eine perspektivische Ansicht eines Rotorabschnitts im Bereich einer Befestigungsnut sowie ein als Wellenkeil ausgebildetes Verriegelungsglied zum Einführen in eine Verriegelungsaussparung.

An exemplary embodiment of a turbine according to the invention will be explained in more detail below with reference to the attached schematic drawings. It shows:

Fig. 1

a perspective view of a turbine rotor section with a blade mounting groove,

Fig. 2a

1 shows an axial section view of the turbine rotor according to FIG. 1 with a blade root inserted therein and a blocking element located in a mounting position, FIG.

Fig. 2b

the sectional view of the turbine rotor according to FIG. 2a in which the blocking element is displaced into a blocking position, as well as

Fig. 3

a perspective view of a rotor portion in the region of a fastening groove and a locking member designed as a shaft wedge for insertion into a locking recess.

1 shows a portion of a turbine rotor 10 according to the invention in the region of a blade attachment groove 12. The blade attachment groove 12 has fir tree profile, which is designed to receive a turbine blade with a fir-tree-shaped foot. FIG. 2a shows a portion of such a blade root 18 inserted into the blade attachment groove 12. In an embodiment which is not shown, the rotor and blade root may also have a dovetail-shaped profile. The blade root 18 is inserted into the blade attachment groove 12 axially with respect to the rotor for mounting the turbine blade. Here, the blade root 18 along a straight or slightly curved path in a relation to the rotor axis pivoted by a small angle orientation in the Schaufelbefestigungsnut 12th introduced. In this case, there is a blocking element 16 arranged on a bottom region 14 of the blade attachment groove 12 in the assembly position shown in FIGS. 1 and 2a. In the mounting position is a radially outwardly facing shear piece 16a of the locking element 16 in the central region of the bottom portion 14 of the Schaufelbefestigungsnut 12. The locking member 16 has, in addition to the shear piece 16a on a perpendicularly extending bottom piece 16b. The bottom piece 16b extends in the tangential direction with respect to the rotor 10 and is arranged in a locking groove 26b of the rotor 10 arranged in the bottom area 14 of the rotor 10.

For insertion of the blade root 18 in the Schaufelbefestigungsnut 12 of the rotor 10, the locking element 16 is arranged in the center position 10 of the Schaufelbefestigungsnut 12 shown in FIGS. 1 and 2a, with respect to the bottom portion 10 of the Schaufelbefestigungsnut 12, so that the shear piece 16a in one at the bottom of the blade root 18 centrally provided locking groove 26a of the blade root can be performed. This position of the blocking element 16 is also referred to as a mounting position. If the blade root 18 is fully inserted into the Schaufelbefestigungsnut 12, the locking member 16 is moved by means of a dedicated tool, such as a mandrel according to FIGS. 2a and 2b to the right in Sperrausnehmungen 20 and 22 of the rotor 10 and the blade root 18. Then, a locking member 28 is inserted into a locking recess 26 composed of a locking groove 26a of the blade root and a locking groove 26b of the rotor 10. The locking member 28 is designed as a wave wedge, as shown in FIG. 3. By inserting the locking member 28, the blocking element 16 according to FIGS. 2a and 2b is held on the right in the blocking recesses 20 and 22 of the rotor 10 and of the blade root 18. As shown in Fig. 1, the locking recess 20 of the rotor is designed as a radial recess with a semicircular side wall 24. The semicircular side wall 24 has portions that are transverse to the axial direction of the rotor oriented abutment surfaces 24a and 24b for the shear piece 16a of the locking element 16 serve.

The corresponding locking recess 22 of the blade root 18 has an analogous profile to the profile of the locking recess 20, so that the locking element 16 is positively received by the locking recesses 20 and 22 when arranged in the locking position. In this position, the locking element 16 secures the blade root 18 against axial displacement relative to the rotor 10 by shear stress of the locking element 16. Upon introduction of the formed as a wave wedge locking member 28, the waves thereof are pressed flat. Thereafter, wedge ends 28a and 28b of the locking member 28 are preferably bent radially inwardly to secure the locking member 28 itself against axial displacement. Now, if the blade root 18 are removed again from the Schaufelbefestigungsnut 12, first the wedge ends 28a and 28b of the locking member 28 are bent back and the locking member 28 removed by expulsion. With a pin punch, the blocking element 16 is then pushed back into the blade mounting position according to FIG. 2a via an unlocking recess 30 provided as a bore or groove in the low-stressed region of the blade root 18. The Entriegelungsaussparung 30 can be seen in Fig. 3. When the blade root 18 is removed, it again slides over the blocking element 16 as during installation and can then be removed from the blade fastening groove 12.

Claims (11)

Turbine for a thermal power plant with a rotor (10),
at least one blade having a blade root (18) in engagement with the rotor (10) via a groove / web connection (12, 18),
and a blocking element (16) for blocking a relative movement between the blade root (18) and the rotor (10) in the axial direction of the rotor (10),
characterized in that
in the blade root (18) and the rotor (10) is provided in each case a locking recess (20, 22) for receiving such a blocking element (16),
that the blocking element (16) under shear stress blocks a relative movement between the blade root (18) and the rotor (10) in the axial direction of the rotor (10). Turbine according to claim 1,
characterized in that
the blocking recesses (20, 22) in the blade root (18) and the rotor (10) are designed to receive the blocking element (16) in a form-fitting manner at least in the axial direction of the rotor (10). Turbine according to claim 1 or 2,
characterized in that
the respective locking recess (20, 22) in the blade root (18) and / or the rotor (10) is designed as a radial depression with a profile, in particular having a circular segment. Turbine according to one of the preceding claims,
characterized in that
in the respective locking recess (20, 22) in the blade root (18) and / or the rotor (10), the locking member (16) from a blade mounting position for mounting or dismounting the blade root (18) in a blocking position for blocking an axial direction Rotor (10) taking place relative movement between the blade root (18) and the rotor (10) is displaceable. Turbine according to one of the preceding claims,
characterized in that
the respective locking recess (20, 22) in the blade root (18) and / or the rotor (10) has a transverse to the axial direction of the rotor (10) extending contact surface (24a, 24b). Turbine according to one of the preceding claims,
characterized in that
the blade root (18) and / or the rotor (10) has a locking recess (26, 26a, 26b) extending in the axial direction of the rotor (10),
in particular a locking groove,
and a locking member (28) guided in the locking recess (26, 26a, 26b),
which is designed for displacing the blocking element (16) into a blocking position in the blocking recesses (20, 22) of the blade root (18) and of the rotor (10),
in which the blocking element (16) blocks a relative movement between the blade root (18) and the rotor (10) in the axial direction of the rotor (10). Turbine according to claim 6,
characterized in that
the locking member (28) is designed as a wedge piece. Turbine according to claim 6 or 7,
characterized in that
the locking member (28) rod-shaped,
is designed in particular as a wave wedge. Turbine according to one of claims 6 to 8,
characterized in that
the locking member (28) is bendable at its ends (28a, 28b) for securing against axial displacement. Turbine according to one of the preceding claims,
characterized in that
the blade root (18) and / or the rotor (10) has an unlocking recess (30),
in particular a bore (30) and / or a groove, which for receiving a Entriegelungswerkzeuges, in particular a pin punch for pushing out the locking element (16) from a locking position in the locking recesses (20, 22) of the blade root (18) and the rotor (10 )
in which the blocking element (16) blocks a relative movement between the blade root (18) and the rotor (10) in the axial direction of the rotor (10),
is trained. Turbine according to claim 10,
characterized in that
the Entriegelungsaussparung (30) extends in a low-stressed region of the blade root (18).

Images