The invention relates to a turbine wheel arrangement for a gas turbine having two successive turbine wheels rotating in opposite directions.
Currently known gas turbines are designed for the highest possible performance with the highest degree of efficiency, as a consequence of which the components and materials used are strained to the limits of acceptability. This applies in particular to the turbine blades of the first turbine stage which are subjected to the most extreme demands, the result of which is that it is necessary to use very expensive materials and to implement complex cooling measures for cooling the blades. Added to this are loads due to high mechanical stresses caused by high flow velocities, but above all the high centrifugal forces resulting from the high rotational speeds. On the whole, it is difficult with such designs to achieve an overall efficiency of greater than 35%.
In steam turbine manufacturing, it is known to design stationary guide wheels of axial turbines with Laval nozzle channels that are oriented at an angle of approximately 45° relative to the circumferential direction.
A gas turbine is known from AT 239606 in which combustion gases are guided outwardly via two oppositely aligned radial channels and subsequently diverted in the circumferential direction and directed through Laval nozzle-like outlet channels on blades of an oppositely disposed rotating blade wheel.
The object of the invention is to provide a gas turbine which is distinguished from conventional turbines by lower temperature stress of the turbine stage and which makes possible a high temperature and pressure gradient from the combustion chamber to the turbine blades within a broad power range, so that high thermal efficiency can be achieved thereby.
The invention arises from the features of the independent claims. Advantageous refinements and embodiments are the subject matter of the dependent claims.
The advantageous effect of the invention is that the thermal energy and compressive energy of the gas at the nozzle inlet are largely converted into flow energy at the outlet of the turbine stage. The impulse force of the nozzles drives the turbine wheel. The gas exiting the Laval nozzles has a very high flow velocity in excess of mach 1 and is directed to the blades of the second turbine wheel in the direction of flow, as a result of which a torque and a rotation are produced counter to the direction of rotation of the first turbine wheel. In this configuration, the speed of the gas jet is substantially greater than the peripheral speed of the turbine blade. Thus, the kinetic energy remaining in the flow jet from the first energy conversion in the Laval nozzles is utilized. In this case the second turbine wheel is designed so that ideally the tangential speed at the outlet virtually disappears.
By suitably controlling the stresses at each wheel, for example, using generators, the rotational speeds of the two rotors coupled to the turbine wheels can be set as desired, allowing the operational states of the two systems to be optimally set without adjusting systems.
With the invention it is possible to separate the combined stresses thermally, mechanically and based on centrifugal force. As a result, a release occurs in Laval nozzles which reduces virtually all the thermal and compressive energy and which converts it into kinetic energy. Thus, the material stresses are reduced substantially to this area. The Laval nozzles themselves may be manufactured from suitable, temperature-resistant materials such as ceramics or metal alloys and are able to withstand the thermal loads. Accordingly, the kinetic energy remaining in the gas jet is fully utilized as a result of the momentum in the second turbine stage. Based on the counter-rotation principle it is possible to reduce by half the required rotational speed, consequently reducing significantly the stresses caused by centrifugal forces.
Based on the concept according to the invention, it is possible to achieve very high compression ratios of >25, high combustion chamber temperatures of >2,000° C. and, as a result, high thermal efficiency of >60% and overall gas turbine efficiency of >50%.
A further significant advantage of the invention is that the gap between the wheels has no significant effect on efficiency. Furthermore, the components can be more simply and inexpensively manufactured than is the case with conventional turbines, because a single stage turbine is sufficient for achieving the entire energy conversion. As a further advantage, cooling is required only at the Laval nozzles, while a second turbine wheel does not rely on cooling, with the result that the losses in conventional turbines resulting from the significant amount of bleed air for cooling the turbine are prevented.
According to an advantageous refinement of the invention, the gas turbine comprises an inner rotor, on the outside of which are mounted multiple first blade rows of a multi-stage axial compressor and the second turbine wheel in the direction of flow, in that said gas turbine further comprises a hollow shaft, on the inside of which are mounted multiple second blade rows of the axial compressor which alternate in the axial direction with the first blade row, in that also mounted on the hollow shaft is at least one combustion chamber and the first turbine wheel. Since the blade rings of the shaft rotating in opposite directions alternate in the axial direction of the compressor, virtually any higher number of stages counter-directional in design are possible. In this configuration, the speed of rotation of the two shafts is preferably the same. However, in certain applications, for example, in booster mode, a difference in speed of rotation between the two shafts is also feasible.
Further advantages, features and details are set forth in the following description, in which exemplary embodiments are described in detail with reference to the drawing. Features described and/or depicted form per se or in any meaningful combination the subject matter of the invention. if applicable, independently of the claims as well, and in particular may also constitute the subject matter of one or more separate applications. Identical, similar and/or functionally similar parts are identified with similar reference numerals.
In the drawings
Every second blade ring of the axial compressor 12 and the second turbine wheel 20 are jointly mounted on an inner rotor 22 which is supported via a bearing 24 on a stationary axle 26. Also attached to the inner rotor 22 is the rotor 28a of a first generator, the external stator of which is not shown.
Supported on the inside of a hollow shaft-like outer rotor 30 is the other blade ring of the axial compressor 12, in addition to the blade ring of the radial compressor 14, the combustion chamber 16 and the turbine wheel 18. The outer rotor 30 is supported by a first bearing 32a on the stationary axle 26 and by a second bearing 32b on the inner rotor 22. In addition, the outer rotor 30 is joined via a first blade ring 34 to a rotor hub 36 which is supported by the front bearing 32a on the shaft 26. A rotor 38b of a second generator is attached radially outwardly to the outer rotor 30, the external stator of which is not shown.
Outer turbine blades (44) of the second turbine wheel 20 are arranged radially outside the shaped parts 40 which are impacted by the supersonic gas flow exiting the flow channels 42 and are thereby caused to rotate in a direction opposite to the first turbine wheel 18.
During operation, air is drawn into the inlet of the gas turbine 10a depicted in
The rotation of the first turbine wheel 18 is transmitted via the outer shaft 30 to the radial compressor 14 as well as to the blade row of the axial compressor 12 on the outside of the rotor and to the generator rotor 28b. The counter rotation of the second turbine wheel 20 is transmitted to the generator rotor 28a and via the inner rotor 22 to the compressor blades of the axial compressor 12 on the inside of the rotor.
The gas turbine shown in
The gas turbine embodiment 10b also comprises a multi-stage axial compressor 12, which in turn comprises a hollow shaft 30, to which every other blade row is attached in the axial direction. Provided between these are blade rows that are attached to a main rotor 52. The main rotor 52 is mounted by means of bearing 24 on the one hand on an axle 26 and on the other hand on a housing not shown. Further, a Pelton turbine wheel 54 is molded onto the main rotor 52, represented in cross-section in
The hollow shaft 30 comprises a blade ring of a radial compressor 14 and is joined to a rotating combustion chamber 16 and to a nozzle wheel 58. A first blade ring 34 connects the hollow shaft 30 to a hub shaft 60, which in turn is supported by a front bearing 32a on a housing not shown. At the other end the nozzle wheel 58 is supported by a bearing 32b on the main rotor 52. Provided on the hub shaft 60, as on the main rotor 52, is a mounting flange 62 for discharging the output generated.
During operation, the air stream enters the multi-stage axial compressor 12 through the first blade ring 34 where it is compressed. Subsequently, further compression takes place in the radial compressor 14, from where the air stream is fed to the co-rotating combustion chamber 16. There, fuel is added and the mixture is combusted. The combustion gases flow through the nozzles 64 where they act on the Pelton blades 66. As a result, the nozzle wheel 58 rotates counterclockwise as seen in
In one variation, the turbine stage 18 may be connected to the air supply channel 80, and in a second variation the turbine stage 18 is separate from the air supply channel 80, and thus, the air supply channel 80 forms the housing of the gas turbine.
Number | Date | Country | Kind |
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10 2010 048 434.2 | Oct 2010 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/DE11/01849 | 10/4/2011 | WO | 00 | 4/12/2013 |