The subject matter disclosed herein relates to turbomachines. More particularly, the subject matter relates to gas turbomachines and associated maintenance apparatuses.
Conventional turbines, such as gas turbines, generally include three sections: a compressor section, a combustor section and a turbine section. The compressor section compresses ambient air, and provides that compressed air to the combustion section where it is combined with fuel to generate a heated working fluid (gas). The heated gas is provided to the turbine section, where it impacts turbine blades to drive rotation of the turbine rotor shaft.
The rotor shaft is sometimes coupled with a dynamoelectric machine such as a generator (e.g., via a coupled shaft), which converts the rotational energy of the turbine into electrical energy. In other cases, the rotor shaft is coupled with an accessory box or other system. In either case, the rotor shaft is coupled with an external shaft (e.g., from the accessory box or dynamoelectric machine). This coupling is surrounded and protected by a thrust bearing. The thrust bearing can provide mechanical support to the shafts, and dissipate thrust from the turbine during operation. The thrust bearing is located adjacent the inlet bellmouth of the turbine's compressor section, and is protected by a bearing housing. The bearing area also includes a journal bearing, which withstand radial loads applied to the rotor. Additional components within the bearing housing area can include lift oil piping, thermocouple wiring, and other instrumentation.
When performing maintenance on the shafts or the thrust bearing, conventional approaches require completely removing the inlet bellmouth in order to access the bearing (and shafts) under the housing. The inlet bellmouth is formed in two halves around the turbine shaft, and is interconnected with other components in the compressor section. Because of the significant weight of the bearings (e.g., up to 225 kilograms per half), conventional approaches require clearance in order to manipulate these components. Conventional approaches for maintenance on the bearing area, including thrust and journal bearings, involve the use of an overhead crane that lifts the upper half of the inlet bellmouth to remove it from the assembly. As such, maintenance approaches that require complete removal of the inlet bellmouth are expensive, cumbersome and time-consuming.
Various embodiments include apparatuses for performing maintenance on a gas turbine bearing area, along with related methods. One apparatus can include: a set of rails sized to couple with the gas turbine and rest coaxially with a bearing in the bearing area adjacent the gas turbine, the set of rails for supporting a portion of a housing of the bearing; a first platform spanning between the set of rails; a lifting device coupled to the first platform for engaging an inlet bellmouth of the gas turbine; and a second platform suspended from the set of rails sized to accommodate an operator.
A first aspect of the disclosure includes an apparatus for performing maintenance on a bearing area of a gas turbine, the apparatus having: a set of rails sized to couple with the gas turbine and rest coaxially with a bearing in the bearing area adjacent the gas turbine, the set of rails for supporting a portion of a housing of the bearing; a first platform spanning between the set of rails; a lifting device coupled to the first platform for engaging an inlet bellmouth of the gas turbine; and a second platform suspended from the set of rails sized to accommodate an operator.
A second aspect of the disclosure includes a method of performing maintenance on a bearing area of a gas turbine, the method including: separating sections of an inlet bellmouth of the gas turbine without removing the sections of the inlet bellmouth from the gas turbine; removing a housing from over a bearing in the bearing area within the gas turbine; mounting a bearing maintenance apparatus adjacent the inlet bellmouth and the bearing, the bearing maintenance apparatus having: a set of rails sized to couple with the gas turbine and rest coaxially with the bearing, the set of rails for supporting the bearing housing; a first platform spanning between the set of rails; a lifting device coupled to the first platform for engaging the inlet bellmouth; and a second platform suspended from the set of rails sized to accommodate an operator; and performing maintenance on the bearing area while the sections of the inlet bellmouth remain separated.
A third aspect of the disclosure includes a method of performing maintenance on a gas turbine having a shaft, a bearing for the shaft, a bearing housing and a turbine inlet bellmouth adjacent the bearing housing, the method including performing in-situ maintenance on a bearing area of the gas turbine by: separating sections of an inlet bellmouth of the gas turbine without removing the sections of the inlet bellmouth from the gas turbine; removing a housing from over the bearing of the gas turbine; mounting a bearing maintenance apparatus adjacent the inlet bellmouth and the bearing; and performing maintenance on the bearing area while the sections of the inlet bellmouth remain separated, wherein while performing the in-situ maintenance, the bearing maintenance apparatus is mounted to the gas turbine such that an operator can access the bearing area from below the shaft.
These and other features of this disclosure will be more readily understood from the following detailed description of the various aspects of the invention taken in conjunction with the accompanying drawings that depict various embodiments of the invention, in which:
It is noted that the drawings of the invention are not necessarily to scale. The drawings are intended to depict only typical aspects of the invention, and therefore should not be considered as limiting the scope of the invention. In the drawings, like numbering represents like elements between the drawings.
As noted, the subject matter disclosed herein relates to turbomachines. More particularly, the subject matter relates to gas turbomachines and associated maintenance apparatuses for gas turbomachine bearings and associated equipment.
In contrast to conventional approaches, various embodiments of the disclosure include a maintenance apparatus for a gas turbine configured to access and remove components, such as the turbine thrust bearing, journal bearing, piping and/or wiring without completely removing the turbine's inlet bellmouth. That is, the maintenance apparatuses and approaches disclosed according to various embodiments allow for access of the bearing area and related housing from underneath the turbine assembly, obviating the overhead crane used in conventional approaches.
Turning to
Apparatus 2 is configured (e.g., sized) for use in performing maintenance on a bearing area 14, which can include a thrust bearing 13, journal bearing 15 and/or other wiring and piping proximate thrust bearing 13 and journal bearing 15 (
As shown, apparatus 2 can include a set of rails 20 (
As noted herein, rails 22, 24 can rest coaxially with thrust bearing 13, journal bearing 15 (as well as housing 18), and the primary axis (of rotation) of turbine 6 (direction A,
In various embodiments apparatus 2 further includes a first platform 28 spanning between the set of rails 20 (rails 22, 24), and a lifting device 30 coupled (e.g., mechanically fastened, bolted/screwed, integrally formed, etc.) to first platform 28 for engaging inlet bellmouth 17 of turbine 6. Lifting device 30 can include a winch or a pneumatic lift, and in some cases, can be configured to rotate about an axis aL to transport components for use in maintenance of bearing area 14 (e.g., on thrust bearing 13, journal bearing 15, etc.). Additionally, lifting device 30 may be used to modify a position of inlet bellmouth 17, e.g., by raising or lowering an upper half 17A of inlet bellmouth 17 relative to first platform 28. Lifting device 30 may also be used to transport other components 31 to/from first platform 28.
In various embodiments, apparatus 2 can include a second platform 32 suspended from set of rails 20 (e.g., rail 22 and/or rail 24), where second platform 32 is sized to accommodate an operator (e.g., a human operator). In various embodiments second platform 32 is coupled with rails 20 by a suspension system 34, which may include a fixed support 36 and a hinged support 38. In some cases, second platform 32 is positioned below bearing area 14 (and housing 18) while apparatus 2, 12 is mounted to turbine 6, such that an operator can access bearing area 14 from underneath shaft 10. In various embodiments, second platform 32 is a single platform (
In some cases, apparatus 2 further includes at least one cross-brace 40 spanning between rails 22, 24, e.g., for stabilizing rails 22, 24. Cross-brace(s) 40 may be located at one or more points along set of rails 20, including proximate platforms 28, 32. Cross-braces 40 can be used for torsional and bending support/bracing.
In various embodiments, apparatus 2 further includes a cart system 42 coupled with rails 22, 24, for sliding bearing housing 18 axially along set of rails 20. That is, according to various embodiments, cart system 42 is configured to support a portion (e.g., upper half 18A) of bearing housing 18 and allow that portion of housing 18 to move along the axis of rails 22, 24 such that an operator can access the bearing area 14. Cart system 42 can include a mechanical rail system (e.g., a gear-based rail system), a hydraulic rail system (e.g., using a hydraulic pump and cylinders), or any other suitable transport system coupled to rails 22, 24 and capable of moving axially along rails 22, 24. As described herein, rails 22, 24 are spaced such that bearings (e.g., thrust bearing 13 and/or journal bearing 15) are configured to be located between those rails 22, 24 while apparatus 2, 12 is mounted to turbine 6. In some cases, an additional cart system 42A is used to support and/or transport lifting device 30, e.g., along rails 22, 24.
In some cases, each rail 22, 24 includes two distinct rail sections 22A, 22B and 24A, 24B coupled at axial ends 50 of those sections. In various embodiments, the distinct rail sections 22A, 22B and 24A, 24B can be configured to couple and uncouple to allow access to the space between turbine 6 and an adjacent system (e.g., dynamoelectric machine 8). In these instances, rail sections 22A, 22B and 24A, 24B can be separately inserted in an area 52 (
According to various embodiments, apparatus 2, 12 may be used in a method of performing maintenance on bearing area 14.
Process P1: separating sections (upper half 17A and lower half 17B) of inlet bellmouth 17 of gas turbine 6 without removing the sections 17A, 17B of inlet bellmouth 17 (
Process P2: lifting housing 18 within the bearing area 14. This can include using a jack or other lifting device to separate upper half 18A of housing 18 from the lower half of housing 18 (lower half not shown). In some cases, this process is performed by lifting housing 18A with mechanical screws 60 (
Process P3: mounting bearing maintenance apparatus 2 adjacent inlet bellmouth 17 and bearing area 14. This process can include coupling apparatus 2, 12 to turbine 6, e.g., via mounts 26, and to dynamoelectric machine 6, in various embodiments. In various embodiments, bearing housing 18, e.g., upper half 18A of housing 18 can be loaded onto cart system 42 to slide that portion of housing 18 axially relative to thrust bearing 13 and journal bearing 15 (and allow for maintenance on thrust bearing 13 and/or journal bearing 15, along with other components in bearing area 14). In some cases, apparatus 2 can be at least partially assembled on location, but in other cases, one or more portions of apparatus 2 are pre-assembled. In an example where apparatus 2 is at least partially assembled on location: once the inlet bellmouth 17A is lifted and secured, the bearing housing 18 will be lifted high enough off of the lower half 17B of inlet bellmouth's surface such that the maintenance apparatus 2 can be configured underneath. In some cases, rail sections 22B are installed first, and then mounts 26 are used to couple apparatus 2 to dynamoelectric machine 8 and/or an accessory gear box (not shown). Subsequently, rail sections 22A can be added to rail sections 22B, along with cross-brace(s) 40. Platforms 28 and 32 may also be added, and cart system 42 (e.g., including rollers and/or a jib system) can be installed. As described herein, housing 18A can be loaded onto cart system 42 for transport along apparatus 2.
Process P4: performing maintenance on bearing area 14 while sections 17A, 17B of the inlet bellmouth 17 remain separated (depicted in
As described herein, during the maintenance process described with respect to
As noted herein, apparatus 2 can eliminate or significantly reduce the overhead obstacles that are present in conventional approaches to access bearing area 14. These conventional approaches require completely lifting the bellmouth 17A with a crane to access bearing area 14. Occasionally, maintenance operators attempt to perform some of this maintenance without tooling or with makeshift tooling, which is both dangerous and time consuming due to the heavy part manipulation in a confined space. Further, due to the weight of components in bearing area 14, e.g., the bearing housing 18 which may weigh thousands of pounds, apparatus 2 can be used to replace laborious, dangerous and time-consuming transportation processes conventionally performed by hand.
In one example process according to embodiments: The bearing housing 18 is first removed as explained herein. The thrust bearing 13 is then removed once the bearing housing 18 is separated. The thrust bearing 13 is an assembly made up of an upper and lower half, one forward and one aft assembly, including thrust pads and a thrust “cage” (holding pads in place). Thrust bearing 13 may also include instrumentation on the thrust bearing pads, such as thermocouples at various locations. The pads and sometimes the cages (depending upon size) can be removed by hand. If not removed by hand, in some cases there are custom lifting brackets for rigging and lifting the thrust cages with the jib and roller assembly. Next, the upper half journal bearing 15 can be lifted and removed. This may involve assisted lifting because the journal bearing halves can weigh between 50 kilograms (kg) to 250 kg (˜100-500 pounds (lbs)) each, depending upon the gas turbine frame size. After the upper half of journal bearing 15 is removed, the lower half is isolated from the weight of the rotor (shaft 10) so that it can roll to top dead center for lifting and complete removal. There are various conventional methods of “jacking” or lifting the rotor (shaft 10), e.g., approximately 0.025-0.040 centimeters (˜0.010-0.015 inches). The shaft 10 can be lifted using mechanical and/or hydraulic systems, further described herein with reference to
This written description uses examples 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 any devices or systems and performing any incorporated methods. The patentable scope of the invention is defined by the claims, and may include other examples that occur to those skilled in the art. Such other examples are intended to be within the scope of the claims if they have 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 languages of the claims.
Number | Date | Country | Kind |
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17461598.9 | Sep 2017 | EP | regional |
This application is a continuation filing of, and claims priority to, U.S. patent application Ser. No. 16/037,326 (filed Jul. 17, 2018), which itself claims priority to European Patent Application No. EP 17461598.9 (filed Sep. 1, 2017), the entire contents of each of which are incorporated by reference in its entirety.
Number | Date | Country | |
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Parent | 16037326 | Jul 2018 | US |
Child | 17192115 | US |