DE102012100013A1 - Axial holding device for a turbine system - Google Patents

Abstract

An axial securing device (50) for a turbine system (10) is disclosed. The axial securing device (50) has a recess (52) which is defined in a contact surface (62, 64) of a turbine component (34) or a retaining structure (32). The recess (52) has a first Axiallastfläche (94). The axial securing device (50) further comprises a locking device (54), which comprises a base element (56) and a pivoting element (58). The base member (56) is associated with a mating surface (62, 64) of the other member, turbine component (34) or support structure (32). The pivoting element (58) is arranged to engage in the recess (52) and has a first axial load mating surface (102). By the engagement of the pivot member (58) and the recess (52), the first Axiallastfläche (94) and the first Axiallast counter surface (102) interact and the axial movement of the turbine component (34) relative to the support structure (32) in the at least to prevent a direction.

Description

FIELD OF THE INVENTION

The subject matter described herein relates generally to turbine systems, and more particularly to axial securing devices for securing components in turbine systems.

GENERAL PRIOR ART

Turbine systems are widely used in areas such as power generation. For example, a conventional gas turbine system includes a compressor, a combustor, and a turbine. A conventional gas turbine further includes a rotor having a plurality of impeller blades mounted on disks in the compressor and turbine parts thereof. Each blade has a blade over which pressurized or pressurized fluid flows and a plate at the base of the blade that defines the radial inner boundary for the air or fluid flow. For attachment of the blades to the impeller disks, the blades may have a suitable attachment, such as a root or a dovetail, which is adapted to engage a complementary mounting cavity at the periphery of the disk.

In many cases, the vanes located in the impeller disks may shift during operation of the system, may slip or loosen relative to the impeller disks, possibly allowing air or fluid flow leakage or other damage to the system. Consequently, devices for securing the blades with respect to the impeller disks may be desired.

One prior art method of axially securing blades in impeller disks involves scoring. The notching creates a press fit between two components, for example between a blade and impeller disk. The blade and the impeller disc are connected, and then the device connecting the blade and the impeller disc is deformed to make the interference fit. However, the use of scoring to secure blades in impeller disks has many disadvantages. For example, the blades have to be replaced after a certain period of use, for example due to wear or damage. Each time a bucket is replaced, the bucket must be staked elsewhere with the impeller disc. Using the notch to secure the spare vane in the impeller disk is a time consuming process. The locations available on the impeller disc for notching are also generally limited. After a certain number of exchanges, jobs may not be available. The unavailability of Vererbstellen thus requires the replacement of the impeller disc. Replacing the impeller disk is both time consuming and costly due to the cost of the impeller disk and the production downtime of the turbine system during replacement.

In the art, therefore, an improved safety device would be desirable for securing vanes and other useful components in impeller disks and other suitable support structures. For example, an axial securing device that prevents the axial movement of the blades and other components relative to the impeller disks and other support structures would be advantageous. It would also be desirable to have a securing device which ensures efficient and inexpensive replacement of the blades and other components and which reduces the need for replacement of the impeller disks and other support structures or eliminates the need for replacement.

BRIEF DESCRIPTION OF THE INVENTION

Aspects and advantages of the invention will be set forth in part in the description which follows, or may be obvious from the description, or may be learned by practice of the invention.

In one embodiment, an axial securing device for a turbine system is disclosed. The axial securing device has a recess defined in a contact surface of a turbine component or a support structure. The recess has a first Axiallastfläche. The axial securing device also has a locking device, which comprises a base element and a pivoting element. The base member is associated with a contact surface of the other member, turbine component or support structure. The pivoting element is adapted to engage in the recess and has a first axial load counter-surface. Through the engagement of the pivot member and the recess, the first axial load surface and the first axial load counter surface can interact and prevent the axial movement of the turbine component with respect to the support structure in the at least one direction.

These and other features, aspects and advantages of the present invention will become better understood with reference to the following description and appended claims. The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention.

BRIEF DESCRIPTION OF THE DRAWINGS

A complete and reproducible disclosure of the present invention, including the best mode thereof, directed to one of ordinary skill in the art, is set forth in the description which refers to the accompanying drawings, in which:

1 is a simplified representation of a turbine system,

2 FIG. 3 is a sectional side view of the compressor of a turbine system according to an embodiment of the present disclosure; FIG.

3 3 is an exploded perspective view of a support structure and a turbine component according to an embodiment of the present disclosure;

4 FIG. 4 is an exploded and cross-sectional view of an axial securing device according to an embodiment of the present disclosure; FIG.

5 FIG. 3 is a cross-sectional view of an axial securing device in a first position during assembly according to an embodiment of the present disclosure; FIG.

6 FIG. 3 is a cross-sectional view of an axial securing device in a second position according to an embodiment of the present disclosure; and FIG

7 FIG. 3 is a cross-sectional view of an axial securing device in a first position during disassembly according to one embodiment of the present disclosure. FIG.

DETAILED DESCRIPTION OF THE INVENTION

Reference will now be made in detail to embodiments of the invention for which one or more examples are illustrated in the drawings. Each example is given by way of illustration of the invention, not limitation of the invention. It will be apparent to one skilled in the art that various modifications and variations can be made to the present invention without departing from the scope or spirit of the invention. For example, features illustrated or described as part of one embodiment may be used in another embodiment to produce yet another embodiment. Thus, it is intended that the present invention cover such modifications and variations that fall within the scope of the appended claims and their equivalents.

1 is a simplified representation of a turbine system 10 , The turbine system described here 10 Although generally a gas turbine system, it should be understood that the turbine system 10 The present invention is not limited to gas turbine systems and that any suitable turbine system, including, but not limited to, a steam turbine system, falls within the scope and spirit of the present disclosure.

The system can therefore use a compressor 12 , a combustion chamber 14 and a turbine 16 exhibit. The compressor 12 and the turbine 16 can over a wave 18 be coupled. The wave 18 may be a single wave or a plurality of wave segments coupled together around the shaft 18 to build.

In 2 are different components of the compressor 12 a turbine system 10 shown. A rotor 20 of the compressor 12 For example, a variety of impeller discs 22 exhibit. A variety of shovels 24 can be in an annular arrangement around each impeller disc 22 can be arranged around and can on the impeller disc 22 fixed as discussed below. As discussed below, each of the blades may 24 on a wheel disk 22 be attached by the shovel 24 is pushed in a generally axial direction, so that an approach of the blade 24 in a cavity of the impeller disc 22 intervenes. So that the shovel 24 safely on the impeller disc 22 is attached and around the axial movement of the blade 24 related to the impeller disc 22 To prevent, an axial securing device may be provided to prevent this axial movement.

It should be understood, however, that the present disclosure is not directed to axial blade securing devices 24 in impeller disks 22 in the compressor 12 a turbine system 10 is limited. Rather, the axial securing device according to the present disclosure may be used in conjunction with any suitable retaining structure 32 for securing a suitable turbine component 34 in every part of the turbine system 10 be used. The holding structure 32 and the turbine component 34 may in embodiments an impeller disk 22 or a shovel 24 in the compressor 12 be. The holding structure 32 and the turbine component 34 however, alternatively may include an impeller disk and blade in the turbine 16 or one Sealing device and spacer ring structure in the compressor 12 or the turbine 16 or any other suitable support structure 32 and any other suitable turbine component 34 in the turbine system 10 be.

As in 3 can be shown, the turbine components 34 and the support structures 32 matching approaches 40 and cavities 42 for matching the turbine components 34 and holding structures 32 exhibit. In some embodiments, the approaches may 40 Be swallowtails and the cavities 42 can be shaped and sized to accommodate the swallowtails. The turbine components 34 are generally using the support structures 32 coupled by the approaches 40 along a generally axial axis 44 in the cavities 42 be pushed, as in 3 is shown. The coupling of the approaches 40 in the cavities 42 prevents the movement of the turbine components 34 related to the support structures 32 in the generally radial and tangential direction, however, can not the movement of the turbine components 34 related to the support structures 32 in a generally axial direction. When the approaches 40 with the cavities 42 For example, the lugs are freely movable along the axial axis 44 in that direction 46 or the direction 48 ,

Consequently, as in 3 to 7 is shown, an axial securing device 50 for axially securing a turbine component 34 in a holding structure 32 intended. The axial securing device 50 has a recess 52 and a locking device 54 on. The locking device 54 According to the present disclosure, a base member 56 and a pivoting element 58 on. The recess 52 can generally be found in the turbine component 34 or the support structure 32 be defined and the base element 56 can the other element, turbine component 34 or holding structure 32 to be associated. In embodiments, as in 3 to 7 is shown, for example, the recess 52 the holding structure 32 belong and the basic element 56 can in the turbine component 34 be defined. In alternative embodiments, the recess 52 the turbine component 34 belong and the basic element 56 can in the holding structure 32 be defined.

The turbine component 34 can be a touchpad 62 define and the holding structure 32 can be a touchpad 64 define. The contact surfaces 62 . 64 can at the approach 40 or in the cavity 42 be defined as in 3 to 7 is shown. In embodiments, for example, the contact surface 62 of the turbine component 34 the lower surface of the neck 40 his and the touchpad 64 the holding structure 32 can the area inside the cavity 42 which is set up with the lower surface of the neck 40 match. In alternative embodiments, the contact surface 62 each side or other surface of the neck 40 his and the touchpad 64 can the area inside the cavity 42 which is set up with this surface of the approach 40 match. In further alternative embodiments, the contact surfaces 62 . 64 adjacent to the neck 40 and the cavity 42 be defined. The contact surface 64 For example, the edge of the support structure 32 his and the touchpad 62 of the turbine component 34 may be the area that is set up with this area of the support structure 32 match. The contact surfaces 62 . 64 Generally fit together when the turbine component 34 and the support structure 32 be coupled with each other. The recess 52 can in the touchpad 62 or 64 of the turbine component 34 or the support structure 32 be defined and the base element 56 can the other interface, 62 or 64 , the turbine component 34 or the support structure 32 be associated. In embodiments, as in 3 to 7 is shown, the recess 52 for example, in the contact area 64 the holding structure 32 be defined and the base element 56 can the touch area 62 of the turbine component 34 be associated.

As discussed, the base element 56 the contact surface 62 or 64 be associated. In some embodiments, the base member may 56 for example, at the interface 62 or 64 be mounted. In these embodiments, the base member 56 For example, using a suitable adhesive, mechanical fastener or other suitable mounting device or other suitable assembly method can be mounted. In other embodiments, the base member 56 or a portion thereof, a unit with the interface 62 or 64 form. In other embodiments, as in 3 to 7 is shown, the contact surface 62 or 64 that is the base element 56 is associated, a second recess 72 in it. The basic element 56 can be set up in the second recess 72 intervene. In general, the engagement of the base element prevents 56 and the second recess 72 the axial movement along the axial axis 44 of the base element 56 based on the second recess 72 in at least one direction. For example, as shown, the base element 56 in the second recess 72 be arranged. In some embodiments, the base member may 56 for example using a suitable adhesive, mechanical fastener or other suitable mounting device or other suitable mounting method in the second recess 72 can be mounted and so can in the second recess 72 intervention. In other embodiments, the base element is 56 maybe not at the second recess 72 mounted or otherwise fastened and can easily in the second recess 72 be placed. In these embodiments, the second recess 72 a first axial load area 74 and optionally a second axial load area 76 exhibit. Furthermore, the base element 56 a first axial load mating surface 82 and optionally a second axial load counterface 84 exhibit. If the base element 56 in the second recess 72 can be placed, the first axial load area 74 and the first axial load counterface 82 acting on each other and the axial movement of the base member 56 in one direction, for example in the direction 46 , prevent. Furthermore, in embodiments, the second axial load surface 76 and the second axial load counterface 84 acting on each other and the axial movement of the base member 56 in a second opposite direction, for example in the direction 48 , prevent. The basic element 56 can therefore in these embodiments in the second recess 72 intervention.

In embodiments, the base member 56 from the second recess 72 be taken out. Alternatively, the base element 56 however permanently in the second recess 72 be mounted.

As in 3 to 7 is shown, the pivoting element 58 be set up in the recess 52 intervene. In general, the engagement of the pivot member prevents 58 and the recess 52 the axial movement along the axial axis 44 of the pivoting element 58 related to the recess 52 in at least one direction. For example, to get into the recess 52 to intervene, as in 6 is shown, the pivoting element 58 in the recess 52 be arranged. The recess 52 can be a first axial load area 94 and optionally a second axial load area 96 exhibit. Furthermore, the pivoting element 58 a first axial load mating surface 102 and optionally a second axial load counterface 104 exhibit. When the swivel element 58 in the recess 52 can be arranged, the first axial load 94 and the first axial load counterface 102 acting on each other and the axial movement of the pivoting element 58 in one direction, for example in the direction 46 , prevent and thus the axial movement of the turbine component 34 related to the support structure 32 prevent in this direction. Furthermore, in embodiments, the second axial load surface 96 and the second axial load counterface 104 acting on each other and the axial movement of the pivoting element 58 in a second opposite direction, for example in the direction 48 , prevent and thus the axial movement of the turbine component 34 related to the support structure 32 prevent in this direction. The pivoting element 58 can therefore in these embodiments in the recess 52 intervention.

The pivoting element 58 can, as mentioned, be set up in the recess 52 intervene. The pivoting element 58 For example, based on the base element 56 be swiveling. The pivoting element 58 can be about a pivot 110 swing. The fulcrum 110 may be adjacent to one end of the base member 56 be arranged as in 3 to 7 is shown, or may be adjacent to the base member 56 at any point along the base element 56 be arranged. The fulcrum 110 In general, the pivoting element 58 with the base element 56 connect.

In embodiments, the pivoting element 58 between a first position, as in 5 and 7 is shown, and a second position, as in 4 and 6 is shown, panning. In the first position, the pivoting element 58 from the recess 52 be solved. In the released state, the first axial load area 94 and the first axial load counterface 102 do not interact. The pivoting element 58 can therefore refer to the recess 52 in at least one direction, for example in the direction 46 , allowed to move axially. The turbine component 34 can also be based on the support structure 32 in at least one direction, for example in the direction 46 , allowed to move axially. In the second position, the pivoting element 58 with the recess 52 engage. In the engaged state, the first axial load area 94 and the first axial load counterface 102 interact with each other. The pivoting element 58 can therefore be prevented from referring to the recess 52 in at least one direction, for example in the direction 46 to move axially. The turbine component 34 Further, it can be prevented from relating to the support structure 32 in at least one direction, for example in the direction 46 to move axially.

In some embodiments, the pivot member may 58 be biased towards the second position. The locking device 54 For example, it may include a spring element (not shown) or other suitable biasing device therein. The spring element or the other biasing device may be on the pivoting element 58 a force, such as a tensile or compressive force exerting to the pivoting element 58 to bias toward the second position. In alternative embodiments, the pivoting element 58 but biased toward the first position, have no bias or have any other suitable bias.

In some embodiments, the pivot member may 58 an expansion element 120 exhibit. The expansion element 120 can be set up, the pivoting element 58 to swing from the second position to the first position. In some embodiments, the expansion element 120 For example, be a tab, a handle or another projection. In the expansion element 120 In these embodiments, a pivoting device such as a lever or a person may engage around the pivoting element 58 to swing from the second position to the first position. In other embodiments, the expansion element 120 a groove 122 (please refer 3 ), which are in the pivoting element 58 is defined. In the groove 122 can engage a pivoting device to the pivoting element 58 to swing from the second position to the first position.

In some embodiments, as shown in FIG 7 is shown, the axial securing device 50 Further, a pivoting device, such as a lever 124 , exhibit. The lever 124 can be set up in the expansion element 120 , in embodiments, for example, the groove 122 to engage and the pivoting element 58 to swing from the second position to the first position.

The expansion element 120 and the pivoting device, such as the lever 124 , can the pivoting element 58 from the second position to the first position. As previously discussed, the turbine component may 34 in the first position relative to the support structure 32 allowed to move axially in at least one direction. By pivoting the pivoting element 58 from the second position to the first position, consequently, the turbine component 34 from the holding structure 32 get extended.

The axial securing device 50 Thus, the present invention can provide efficient, inexpensive, and repeatable installation, securing, and removal of turbine components 34 in holding structures 32 enable. As in 5 illustrated and discussed above, for example, the pivoting element 58 the axial securing device 50 in the first position allow a turbine component 34 in a holding structure 32 is mounted. After the turbine component 34 related to the support structure 32 axially to a desired position in the support structure 32 has moved, the pivoting element 58 to swing to a second position, as in 6 is shown. In the second position, the axial securing device 50 the turbine component 34 in the holding structure 32 secure and so the axial movement of the turbine component 34 related to the support structure 32 prevent in at least one direction. To remove the turbine component 34 from the holding structure 32 , as in 7 is shown, the pivoting element 58 be pivoted from the second position to the first position. In the first position, the axial securing device 50 again the axial movement of the turbine component 34 in the holding structure 32 in at least one direction.

The axial securing device 50 The present disclosure may advantageously include the axial movement of turbine components 34 related to holding structures 32 prevent in one or more directions. This prevention of the axial movement can advantageously be the possible escape of a high-temperature stream and / or the escape of coolant between the turbine component 34 and the support structure 32 prevent or reduce. The use of an axial securing device discussed herein 50 Furthermore, an efficient and cost-effective installation and removal of turbine components 34 in holding structures 32 guarantee. The axial securing device 50 may also include the repeated installation and removal of turbine components 34 in holding structures 32 ensure, without frequent replacement of the support structures 32 to make necessary. In addition, existing turbine components 34 and holding structures 32 be retrofitted to axial securing devices 50 taking up the time and expense previously associated with assembling and disassembling these turbine components 34 and holding structures 32 were connected, shortened or lowered.

In this written description, examples are used to disclose the invention, including the best mode, and also to enable any person skilled in the art to practice the invention, including making and using devices or systems and practicing methods contained therein. The patentable scope of the invention is defined by the claims, and may include other examples to which the person skilled in the art thinks. These other examples are intended to be within the scope of the claims if they include structural elements that do not differ from the literal language of the claims, or if they include equivalent structural elements with insubstantial differences from the literal language of the claims.

It is an axial securing device 50 for a turbine system 10 disclosed. The axial securing device 50 has a recess 52 on that in a touchpad 62 . 64 a turbine component 34 or a holding structure 32 is defined. The recess 52 has a first axial load area 94 on. The axial securing device 50 also has a locking device 54 on, which is a basic element 56 and a pivoting element 58 includes. The basic element 56 is a touchpad 62 . 64 of the other element, turbine component 34 or holding structure 32 , belonging. The pivoting element 58 is set up, in the recess 52 to engage and has a first thrust load counter surface 102 on. Through the engagement of the pivoting element 58 and the recess 52 can be the first axial load area 94 and the first axial load counterface 102 acting on each other and the axial movement of the turbine component 34 related to the support structure 32 prevent in at least one direction.

LIST OF REFERENCE NUMBERS

10

Gas Turbine System

12

compressor

14

combustion chamber

16

turbine

18

wave

20

rotor

22

wheel disc

24

shovel

32

holding structure

34

turbine component

40

approach

42

cavity

44

Axial axis

46

First direction

48

Second direction

50

Axial securing device

52

recess

54

locking device

56

base element

58

pivoting element

62

Contact surface (turbine component)

64

Contact surface (holding structure)

72

Second recess

74

First axial load area (second recess)

76

Second axial load area (second recess)

82

First axial load mating surface (base element)

84

Second axial load mating surface (base element)

94

First axial load area (recess)

96

Second axial load area (recess)

102

First axial load counter surface (swivel element)

104

Second axial load mating surface (swivel element)

110

pivot point

120

expansion element

122

groove

124

lever

Claims (15)

Axial securing device ( 50 ) for a turbine system ( 10 ), wherein the axial securing device ( 50 ) Comprising: a recess ( 52 ) in a touchpad ( 62 . 64 ) of a turbine component ( 34 ) or a holding structure ( 32 ), wherein the recess ( 52 ) a first axial load area ( 94 ), and a locking device ( 54 ), which is a basic element ( 56 ) and a pivoting element ( 58 ), wherein the base element ( 56 ) a touchpad ( 62 . 64 ) of the other element, turbine component ( 34 ) or holding structure ( 32 ), wherein the pivoting element ( 58 ), in the recess ( 52 ), and a first axial load mating surface ( 102 ), wherein by the engagement of the pivoting element ( 58 ) and the recess ( 52 ) the first axial load area ( 94 ) and the first axial load mating surface ( 102 ) and the axial movement of the turbine component ( 34 ) relative to the support structure ( 32 ) in at least one direction. Axial securing device ( 50 ) according to claim 1, wherein the pivoting element ( 58 ) in a first position from the recess ( 52 ) is dissolved and the axial movement of the turbine component ( 34 ) relative to the support structure ( 32 ) in the at least one direction and the pivoting element ( 58 ) in a second position in the recess ( 52 ) and the axial movement of the turbine component ( 34 ) relative to the support structure ( 32 ) prevented in the at least one direction. Axial securing device ( 50 ) according to claim 2, wherein the pivoting element ( 58 ) is biased towards the second position. Axial securing device ( 50 ) according to one of claims 2 to 3, wherein the pivoting element ( 58 ) further an expansion element ( 120 ), wherein the expansion element ( 120 ), the pivoting element ( 58 ) to pivot from the second position to the first position. Axial securing device ( 50 ) according to claim 4, wherein the expansion element ( 120 ) a groove ( 122 ) which is in the pivoting element ( 58 ) is defined. Axial securing device ( 50 ) according to one of claims 4 to 5, further comprising a lever ( 124 ), which is arranged in the expansion element ( 120 ) and the pivoting element ( 58 ) to pivot from the second position to the first position. Axial securing device ( 50 ) according to one of claims 1 to 6, wherein the recess ( 52 ) further comprises a second axial load surface ( 96 ), wherein the pivoting element ( 58 ) further comprises a second axial load mating surface ( 104 ) and wherein the interaction of the second axial load surface ( 76 . 96 ) and the second axial load mating surface ( 104 ) the axial movement of the turbine component ( 34 ) based on the support structure ( 32 ) in a second opposite direction. Axial securing device ( 50 ) according to one of claims 1 to 7, wherein the recess ( 52 ) in a touchpad ( 64 ) of the support structure ( 32 ) is defined. Axial securing device ( 50 ) according to one of claims 1 to 8, wherein the contact surface ( 62 . 64 ) of the other element, turbine component ( 34 ) or holding structure ( 32 ), a second recess ( 72 ) and wherein the base element ( 56 ), in the second recess ( 72 ) intervene. Turbine system ( 10 ), comprising: a support structure ( 32 ), wherein the support structure ( 32 ) a touchpad ( 64 ), a turbine component ( 34 ), wherein the turbine component ( 34 ) a touchpad ( 62 ), a recess ( 52 ) in a touchpad ( 62 . 64 ) of the turbine component ( 34 ) or the support structure ( 32 ), wherein the recess ( 52 ) a first axial load area ( 94 ), and a locking device ( 54 ), which is a basic element ( 56 ) and a pivoting element ( 58 ), wherein the base element ( 58 ) a touchpad ( 62 . 64 ) of the other element, turbine component ( 34 ) or holding structure ( 32 ), wherein the pivoting element ( 58 ), in the recess ( 52 ), and a first axial load mating surface ( 102 ), wherein by the engagement of the pivoting element ( 58 ) and the recess ( 52 ) the first axial load area ( 94 ) and the first axial load mating surface ( 102 ) and the axial movement of the turbine component ( 34 ) relative to the support structure ( 32 ) in at least one direction. Turbine system ( 10 ) according to claim 10, wherein the pivoting element ( 58 ) in a first position from the recess ( 52 ) is dissolved and the axial movement of the turbine component ( 34 ) relative to the support structure ( 32 ) in the at least one direction and the pivoting element ( 58 ) in a second position with the recess ( 52 ) is engaged and the axial movement of the turbine component ( 34 ) relative to the support structure ( 32 ) prevented in the at least one direction. Turbine system ( 10 ) according to claim 11, wherein the pivoting element ( 58 ) is biased towards the second position. Turbine system ( 10 ) according to one of claims 11 to 12, wherein the pivoting element ( 58 ) further an expansion element ( 120 ), wherein the expansion element ( 120 ), the pivoting element ( 58 ) to pivot from the second position to the first position. Turbine system ( 10 ) according to one of claims 10 to 13, wherein the recess ( 52 ) further comprises a second axial load surface ( 96 ), wherein the pivoting element ( 58 ) further comprises a second axial load mating surface ( 104 ) and wherein the interaction of the second axial load surface ( 76 . 96 ) and the second axial load mating surface ( 104 ) the axial movement of the turbine component ( 34 ) relative to the support structure ( 32 ) in a second opposite direction. Turbine system ( 10 ) according to one of claims 10 to 14, wherein the recess ( 52 ) in a touchpad ( 64 ) of the support structure ( 32 ) is defined.

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