The subject-matter disclosed herein relates to turbines generally, and more particularly to gas turbines and steam turbines, having an embodiment of a new shroud ring around their rotor blades, and to new methods of limiting leakage of working fluid in a turbine, in particular around tips of the rotor blades within the turbine.
Gas turbines are machines designed to process a working fluid, such as air, that flows inside a flow passage during operation of the machine; in particular, a gas turbine transfers kinetic energy from the flowing working fluid to a rotor of the machine thus turning its rotor.
Turbine efficiency can be defined as the ratio of output mechanical rotor power to input mechanical working fluid power. Turbine efficiency is negatively affected by leakage of working fluid occurring at tips of rotor blades during working operation of the turbine.
However, in the hot-gas turbine of
U.S. Pat. No. 4,784,569 provides a solution for limiting leakage in a (hot-gas) turbine. According to this solution, an appropriately shaped shroud ring around the tips of the rotor blades provides a satisfactory gas seal so that most of the working fluid passes between the blades for efficient energy extraction, and very little is lost by passing over the periphery of the blades. However, in a (hot-gas) turbine at the working temperature, any shroud ring deforms (for example it radially curves inwardly or outwardly) and such deformation can cause damaging contact between the shroud ring and the blades. The shroud ring in the '569 patent is shaped so that it deforms thermally but maintains a running clearance from the blades. Thus, leakage of working fluid can still occur with this type of shroud ring.
Thus, it would be desirable to create a new turbine with low or even no leakage over the periphery of the rotor blades during working operation of the turbine (therefore with smaller clearances than were possible or contemplated by prior technology and designs (including zero clearance) between the tips of the rotor blades and a surface of the shroud ring) and with very little or no risk of contact damage; in particular, it would be desirable to avoid damage of the rotor blades due to contact with the stator: not only A) at working operating condition when the blades rotate at full speed and both the rotor and the stator are hot, but also B) at start-up and shut-down when the blades rotate slowly and both the rotor and the stator are cold, and C) during ramp-up when the blades increase their speed, the rotor is hot and the stator is cold, and D) during ramp-down when the blades decrease their speed, the rotor is cold and the stator is hot.
According to one aspect, the subject-matter disclosed herein relates to a turbine comprising a rotor, a stator and a shroud ring; the rotor comprises at least one array of rotor blades, the shroud ring extends around the array of rotor blades, the stator comprises a casing extending around the shroud ring; the shroud ring is movably coupled with the casing so to allow the casing to thermally expand and contract thereby varying a radial distance between the casing and the shroud ring during operation of the turbine.
Although the present invention was conceived for being applied to gas turbines (in particular its first expansion stages, more in particular its first expansion stage), it may be well applied also to steam turbines.
According to another aspect, the subject-matter disclosed herein relates to a method of limiting leakage of working fluid between a rotor and a stator in a turbine during working operation of the turbine; the turbine comprising at least one rotor wheel with an array of rotor blades and a stator casing extending around the array of rotor blades; the stator casing has radial size dependent from its temperature; the rotor wheel has radial size dependent from its temperature; the method comprising the steps of: arranging a shroud ring having radial size substantially independent from its temperature, positioning the shroud ring concentrically about the rotor wheel, between the array of rotor blades and the stator casing, and mechanically coupling the shroud ring with the casing so that coupling is maintained independently from a temperature of the shroud ring and from a temperature of the casing; at working temperature of turbine, tip regions of the rotor blades of said array are in close proximity to or in contact with an inner region of the shroud ring.
As it will be better explained in the following, a stator casing is made of one or more materials, typically metallic materials, that expand when heated and contract when cooled; therefore, such a stator casing increases its sizes, including its radial size, when heated and decreases its sizes, including its radial size, when cooled. On the contrary, the new shroud ring is made of a material (or more materials) that expands very little when heated and contract very little when cooled this derives for example from a coefficient of thermal expansion lower than 10 μm/m/° C.; therefore, such a shroud ring increases its sizes, including its radial size, very little when heated and decreases its sizes, including its radial size, very little when cooled.
It is to be noted that, as it will be better explained in the following, when the tip regions of the rotor blades of said array are in contact with an inner region of the shroud ring, only a light abrasion occur without any contact damage.
A more complete appreciation of the disclosed embodiments of the invention and many of the attendant advantages thereof will be readily obtained as the same becomes better understood by reference to the following detailed description when considered in connection with the accompanying drawings, wherein:
When a (hot-gas) turbine is working, its components have and maintain substantially constant working temperatures. In considering this condition, the inventors have discovered that it is possible to ideally choose the shape and the size of the turbine components so that there is no leakage of the working fluid over the periphery of the rotor blades during operation of the turbine. In fact, it has been discovered that, unlike prior turbine designs, the clearance between tips of the turbine rotor blades (see e.g. blades 113-1, 113-2 and 113-3 in
During ramp-up of the turbine, the temperatures of the turbine components vary significantly, for example there may be temperature increases of 100-400° C.; to be precise. It is to be noted that each turbine component is subject to a different temperature increase, and that temperature increases do not occur everywhere at the same time; in general, first the turbine rotor heats up and then the turbine stator heats up.
During ramp-down of the turbine, corresponding temperature decreases occur, but, in this case, first the turbine rotor cools down and then the turbine stator cools down.
When the temperature of a turbine component varies, its sizes vary; in particular, a temperature increase corresponds to sizes increases and a temperature decrease corresponds to sizes decreases.
If above-mentioned ideal choice is made, at start-up and shut-down of the turbine, clearance between the tips of the rotor blades and the surrounding stator member is null or small, which is positive.
However, if the above-mentioned ideal choice is made, the turbine blades will get in contact with the stator member extending around them during ramp-up of the turbine as at least one turbine wheel together with its blades will thermally expand before the surrounding stator member; consequently, damages will occur to the blades and the member.
It has been realized that leakage of working fluid over the periphery of turbine rotor blades at start-up, shut-down, ramp-up and ramp-down has a negligible effect on overall turbine efficiency as these operating phases last for relatively short times if compared with the working operating phase.
As disclosed herein, the new turbine is arranged to have low or no leakage when the rotor is hot and thus high efficiency is achieved in particular at working condition, i.e. during working of the turbine. For this purpose a shroud ring is positioned around at least one array of turbine rotor blades providing a satisfactory working fluid seal when the rotor is hot. Such shroud ring is not rigidly coupled with the turbine stator; mechanical coupling of the shroud ring with the stator, in particular with the turbine casing, is such as to allow the casing to thermally expand (and contract) without effecting the position of the shroud ring and thus the leakage at any operating condition of the turbine. The shroud ring (see e.g. member 250 in
Preferably, the shroud ring of the new turbine has sizes substantially independent from its temperature. Initially, when the rotor is cold, there is some leakage in the clearance between rotor and ring; at this stage, the stator is cold and coupled with the rotor; see e.g.
Although the present invention was conceived for being applied to gas turbines (in particular its first expansion stages, more in particular its first expansion stage), it may be well applied also to steam turbines.
Reference now will be made in detail to embodiments of the disclosure, one or more examples of which are illustrated in the drawings. Each example is provided by way of explanation of the disclosure, not limitation of the disclosure. In fact, it will be apparent to those skilled in the art that various modifications and variations can be made in the present disclosure without departing from the scope or spirit of the disclosure. Reference throughout the specification to “one embodiment” or “an embodiment” or “some embodiments” means that the particular feature, structure or characteristic described in connection with an embodiment is included in at least one embodiment of the subject matter disclosed. Thus, the appearance of the phrase “in one embodiment” or “in an embodiment” or “in some embodiments” in various places throughout the specification is not necessarily referring to the same embodiment(s). Further, the particular features, structures or characteristics may be combined in any suitable manner in one or more embodiments.
When introducing elements of various embodiments the articles “a”, “an”, “the”, and “said” are intended to mean that there are one or more of the elements. The terms “comprising”, “including”, and “having” are intended to be inclusive and mean that there may be additional elements other than the listed elements.
Referring now to the drawings, figures from
The difference between this first embodiment and a prior turbine may be understood more easily by comparing the structure at the first expansion stage (corresponding to blades 113-1) of turbine 100 in
an improved and inventive turbine 200 of the first embodiment comprises a rotor 210, a stator 260 and a shroud ring 250; unlike prior teachings, the new shroud ring 250 is coupled with the stator 260 but has a certain possibility of movement, therefore, strictly speaking, it cannot be considered a component of the turbine stator.
Rotor 210 comprises at least one array of blades 213-1 being components of a wheel 212-1 fixed to a shaft 211; typically, the rotor comprises several wheels (with blades) fixed to the same shaft. Shroud ring 250 extends around the array of blades 213-1; as it will be better explained with reference to the second embodiment, a shroud ring may extend around one or two or three or more arrays of blades. Stator 260 comprises a casing extending around shroud ring 250; according to the first embodiment, a shell 261 of the casing extends around shroud ring 250.
With reference to
The geometrical shape of shroud ring 250 according to the first embodiment can be better understood from
Shroud ring 250 (having an annular shape as can be seen e.g. in
The coupling between shroud ring 250 and casing, in particular shell 261, allows substantially no rotation of shroud ring 250 with respect to the casing. In fact, the casing is configured to substantially fix a relative angular position between the shroud ring and the casing during operation of the turbine (i.e. during a time interval from start-up to shut-down); to this regard, detailed description of arrangement 270 of shell 261 follows.
The coupling between shroud ring 250 and casing, in particular shell 261, allows substantially no axial translation of shroud ring 250 with respect to the casing. In fact, the casing is configured to substantially fix a relative axial position between the shroud ring and the casing during operation of the turbine (i.e. during a time interval from start-up to shut-down); to this regard, detailed description of arrangement 270 of shell 261 follows.
Shroud ring 250 and casing, in particular shell 261, may be considered as divided into parts, as shown for example in
Such radial sliding may derive from a part of the shroud ring having a radially-oriented protrusion and a part of the casing having a corresponding radially-oriented recess, the protrusion being arranged to slide in the recess.
Alternatively, such radial sliding may derive from a part of the casing having a radially-oriented protrusion and a part of the shroud ring having a corresponding radially-oriented recess, the protrusion being arranged to slide in the recess.
Still alternatively and preferably and as shown in the figures (see in particular
According to this last possible alternative, it is preferred that the device, in particular key 280, is fixed to the casing, in particular shell 261; in the embodiment of
If coupling through device is chosen, typically, several devices are used. In this case, as shown e.g. in
According to the first embodiment shown in the figures from
Shroud ring 250 is preferably made of or contains a material having a low CTE (=Coefficient of Thermal Expansion), in particular a CTE lower than about 10 μm/m/° C., preferably lower than about 8 μm/m/° C., more preferably lower than about 6 μm/m/° C.; in this way, its sizes, in particular its radial size, is substantially independent from its temperature. Shroud ring 250 may be made or contain a metal-alloy material or a ceramic material.
On the contrary, rotor 210 and/or stator 260 have sizes, in particular radial size, dependent on their temperature. In fact, rotor 210 and/or stator 260 are typically made of one or more materials having a high CTE, in particular a CTE higher than about 10 μm/m/° C., in particular higher than about 12 μm/m/° C., even more in particular higher than about 14 μm/m/° C. Rotor 210 and stator 260 may be made of one or more metallic materials.
Considering
As just explained, tip regions 214 of blades 213-1 may be in close proximity to an inner region 252 of shroud ring 250 at least at working operating condition of turbine 200.
Alternatively and advantageously, tip regions 214 of blades 213-1 may be in contact with an inner region 252 of shroud ring 250 at least at working operating condition of turbine 200. However, in this case, it is preferred that shroud ring 250 comprises a layer 253 of abradable material at inner region 252, and that blades 213 comprise a layer 215 of abrading (or at least one device of abrading material) at their tip regions 214. In this way, when layer 215 touches layer 253, a light abrasion occurs without damages to the blades and/or the shroud ring. Furthermore, in this case, at least at working operating condition of turbine 200, tip regions 214 of the blades 213-1 are partially penetrated into inner region 252 of shroud ring 250, and, advantageously, there is no leakage of working fluid in particular over the periphery of the blades at least during working operation of the turbine.
Advantageously, an array of vanes 967-2 is fitted in shroud ring 950, in particular in a third part 953 (in the form of a cylindrical or conical sleeve) of shroud ring 950. Vanes 967-2 may be considered stator vanes.
Although the present invention was conceived for being applied to gas turbines (in particular its first expansion stages, more in particular its first expansion stage), it may be well applied also to steam turbines.
As it is apparent from the above description, the first embodiment, the second embodiment and other similar turbines implement a method of limiting leakage between a rotor and a stator in a turbine at least during its working operation.
According to this embodiment, the method comprises the steps of:
Typically, the above-mentioned mechanical coupling allows radial movement between the shroud ring and the casing.
The mechanical coupling between the shroud ring and the casing is advantageously made through a plurality of keys.
According to this embodiment, the method may comprise further the steps of:
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102019000001173 | Jan 2019 | IT | national |
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PCT/EP2020/025031 | 1/24/2020 | WO |
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WO2020/151925 | 7/30/2020 | WO | A |
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