Shaft structure and bearing structure for tail end of rotor of gas turbine

Information

  • Patent Grant
  • 6688847
  • Patent Number
    6,688,847
  • Date Filed
    Friday, August 31, 2001
    23 years ago
  • Date Issued
    Tuesday, February 10, 2004
    20 years ago
Abstract
A shaft structure of a rotor tail end of a gas turbine in which a steam passage for supplying and recovering a steam for cooling rotor blades of the gas turbine extends along a center axis of the rotor assembly of the gas turbine is provided, wherein a center hole of the rotor tail end coaxial to the center axis of the steam passage is formed in the rotor tail end. Provision is also made of a thermal sleeve between the steam passage and the inner surface of the center hole of the rotor tail end, so that a thermal insulation gas layer is formed between the inner surface of the center hole of the rotor tail end and the thermal sleeve. The thermal insulation gas layer is isolated gas-tightly and liquid-tightly from the outside.
Description




BACKGROUND OF THE INVENTION




1. Field of the Invention




The present invention relates to prevention or restriction of thermal deformation of a rotor tail end of a steam-cooled gas turbine.




2. Description of the Related Art




The temperature of the burnt gas at an inlet of a gas turbine has been increasing to increase the efficiency of the gas turbine, and in recent years, a gas turbine in which the temperature reaches 1500° C. has been proposed.




A so-called steam-cooled gas turbine, in which the relatively low temperature of steam is used as a coolant, to protect stator blades and rotor blades of the gas turbine from the burnt gas of high temperature, in place of a conventional air cooling system, is being developed. To cool the rotor blades of the gas turbine by steam, it is necessary to provide steam passages for supplying and recovering the cooling steam for the rotor blades, along the center axis of the rotor of the gas turbine.




A rotor assembly of a gas turbine having a plurality of rotor disks which are fastened to each other by spindle bolts so as to rotate together is rotatably supported by a journal bearing. Since the rotor assembly of the gas turbine is very heavy, the gap between the shaft portion of the rotor assembly and the journal bearing is very precisely administrated. However, in the steam-cooled gas turbine, the steam passes through the center portion of the rotor assembly and, hence, the latter and in particularly its shaft portion is thermally deformed, so that the journal bearing can be damaged.




It is an object of the present invention to eliminate these problems, by providing a shaft structure and bearing structure, for a rotor tail end of a steam-cooled gas turbine, in which little or no thermal deformation of the rotor tail end of the gas turbine occurs.




SUMMARY OF THE INVENTION




According to an aspect of the present invention, there is provided a shaft structure of a rotor tail end of a gas turbine in which a steam passage for supplying and recovering a steam for cooling rotor blades of the gas turbine extends along a center axis of the rotor assembly of the gas turbine, wherein a center hole of the rotor tail end coaxial to the center axis of the steam passage is formed in the rotor tail end; a thermal sleeve is provided between the steam passage and the inner surface of the center hole of the rotor tail end; a thermal insulation gas layer is formed between the inner surface of the center hole of the rotor tail end and the thermal sleeve; and the thermal insulation gas layer is isolated gas-tightly and liquid-tightly from the outside.




According to this embodiment of the invention, a thermal sleeve is provided between the steam passage and the inner surface of the center hole of the rotor tail end, so that a thermal insulation gas layer is formed between the inner surface of the center hole and the thermal sleeve. Consequently, when the steam for cooling the turbine rotor blades passes in the steam passage, the heat transfer to the vicinity of the surface of the shaft portion is restricted, thus resulting in little or no thermal deformation of the shaft portion. Moreover, the thermal insulation gas layer is gas-tightly or liquid-tightly isolated from the outside, no steam enters the thermal insulation gas layer. Therefore, if the temperature drops during the stoppage of the gas turbine, no drain of the steam due to the condensation thereof occurs. Thus, no abnormal vibration due to the drain of the steam takes place.




The thermal sleeve can be in the form of a substantially circular cylinder which is welded at its one end to an end disk of the gas turbine and welded at the other end to a shaft portion of the rotor tail end. The thermal sleeve can be provided with a bent portion in the vicinity of the end thereof welded to the shaft portion of the rotor tail end. Consequently, if a temperature difference is caused between the thermal sleeve and the shaft portion, due to the steam passing in the steam passage, the bent portion absorbs the thermal expansion in the axial direction due to the temperature difference to thereby prevent the thermal sleeve from being damaged or broken.




When the thermal sleeve is welded to the end disk or the shaft portion, a pre-tension is preferably applied to the thermal sleeve. The welding of the pre-tensed thermal sleeve to the shaft portion prevents the occurrence of thermal deformation of the thermal sleeve. Moreover, the bent portion and the application of the pre-tension contributes, in combination, to further restriction of the thermal deformation of the thermal sleeve and to a prevention of the thermal sleeve from being damaged or broken.




In another embodiment of the invention, a shaft structure of a rotor tail end of a gas turbine in which a steam passage for supplying and recovering a steam for cooling rotor blades of the gas turbine extends along a center axis of the rotor assembly of the gas turbine, comprises a plurality of shaft portion cooling air passages formed between the steam passage and an outer surface of a shaft portion of the rotor tail end.




According to the embodiment, a plurality of the shaft portion cooling air passages are formed between the steam passage and the outer surface of the shaft portion of the rotor tail end, so that the cooling air passes in the shaft portion cooling air passages. Consequently, when the steam for cooling the turbine rotor blades passes in the steam passage, the shaft portion is cooled by the cooling air passing in the shaft portion cooling air passages, so that the thermal deformation of the shaft portion can be reduced or restricted.




The shaft portion cooling air passages are at least partly formed by directly drilling the shaft portion. Alternatively, the shaft portion can be comprised of a shaft body portion which surrounds the steam passage, and a sleeve fitted on an outer surface of the shaft body portion, so that the shaft portion cooling air passages can be formed at least partly between the shaft body portion and the sleeve.




According to another aspect of the present invention, there is provided a bearing structure for bearing a shaft portion of a rotor tail end of a gas turbine in which a steam passage for supplying and recovering a steam for cooling rotor blades of the gas turbine extends along a center axis of the rotor assembly of the gas turbine, comprising a bearing pad which forms a journal bearing, and seal portions provided on opposite sides of the bearing pad in the axial direction to prevent leakage of a lubricant for lubricating a space between the bearing pad and the shaft portion, the width of the seal portion in the axial direction being such that the surface temperature of the shaft portion of the rotor tail end is maintained below a predetermined temperature by the lubricant, within the width of the bearing pad in the axial direction.




In the bearing structure of the rotor tail end of a gas turbine, since the seal portions provided on opposite sides of the bearing pad are made longer in the axial direction than that of the conventional seal portions, the lubricant supplied to a space between the shaft portion of the rotor tail end and the bearing pad can be spread over a broader surface area of the shaft portion in the axial direction. Consequently, a broader surface area of the shaft portion in the axial direction can be cooled by the lubricant, so that it is possible to maintain the surface temperature of the portion of the shaft portion that is opposed to the bearing pad, at a temperature below a predetermined value. Consequently, it is possible to restrict the thermal deformation, and particularly, the thermal expansion of the shaft portion in the radial direction, at the outer surface portion of the shaft portion that is opposed to the bearing pad, within an allowable limit.




According to another aspect of the present invention, there is provided a shaft structure of a rotor tail end of a gas turbine in which a steam passage for supplying and recovering a steam for cooling rotor blades of the gas turbine extends along a center axis of the rotor assembly of the gas turbine, wherein said rotor tail end is provided therein with a center hole coaxial to the center axis of the steam passage; a thermal sleeve is provided between the steam passage and the inner surface of the center hole of the rotor tail end; a thermal insulation gas layer is formed between the inner surface of the center hole of the rotor tail end and the thermal sleeve; and cooling air is circulated from the outside into the thermal insulation gas layer to enhance the cooling effect of the rotor.




According to another embodiment of the present invention, the thermal sleeve is in the form of a substantially circular cylinder which is welded at its one end to an end disk of the gas turbine and is welded at the other end to a shaft portion of the rotor tail end through a bellows which reduces a thermal stress due to a thermal expansion of the thermal sleeve.




According to another aspect of the present invention, there is provided a shaft structure of a rotor tail end of a gas turbine in which a steam passage for supplying and recovering a steam for cooling rotor blades of the gas turbine extends along a center axis of the rotor assembly of the gas turbine, wherein the rotor tail end is provided therein with a center hole coaxial to the center axis of the steam passage; a steam pipe is provided in the center hole of the rotor tail end; a thermal insulation gas layer is formed between the inner surface of the center hole of the rotor tail end and the steam pipe; and the steam pipe is connected to a stationary steam pipe through seal fins (labyrinth seal), so that the extension of the steam pipe due to the thermal expansion can be absorbed by the sliding movement of the seal fins.




These and other objects, features, and advantages of the present invention will be more apparent from in light of the detailed description of exemplary embodiments thereof as illustrated by the drawings.











BRIEF DESCRIPTION OF THE DRAWINGS




The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate an embodiment of the invention and together with the description serve to explain the principles of the invention. In the drawings, the same reference numerals indicate the same parts.





FIG. 1

is an axial sectional view of a half of a shaft portion of a rotor tail end according to a first embodiment of the present invention;





FIG. 2

is an axial sectional view of a half of a shaft portion of a rotor tail end according to a second embodiment of the present invention;





FIG. 3

is a sectional view taken along the line III—III in FIG.


2


and perpendicular to the shaft;





FIG. 4

is an axial sectional view of a half of a shaft portion of a rotor tail end according to a third embodiment of the present invention;





FIG. 5

is a sectional view taken along the line V—V in FIG.


4


and perpendicular to the axis of a sleeve;





FIG. 6

is an axial sectional view of a half of a shaft portion of a rotor tail end according to a fourth embodiment of the present invention;





FIG. 7

is a schematic view of thermal deformation of a shaft portion of a rotor tail end, which is the drawback of the prior art;





FIG. 8

is a schematic view of thermal deformation of a shaft portion of a rotor tail end when the fourth embodiment of the invention is applied;





FIG. 9

is an axial sectional view of a half of a shaft portion of a rotor tail end according to a fifth embodiment of the present invention;





FIG. 10

is an axial sectional view of a half of a shaft portion of a rotor tail end according to a sixth embodiment of the present invention;





FIG. 11

is an axial sectional view of a half of a shaft portion of a rotor tail end according to a seventh embodiment of the present invention; and





FIG. 12

is an axial sectional view of a half of a shaft portion of a rotor tail end according to a prior art.











DESCRIPTION OF THE PREFERRED EMBODIMENTS




Before proceeding to a detailed description of the preferred embodiments, a prior art will be described with reference to the accompanying relating thereto for a clearer understanding of the differences between the prior art and the present invention.





FIG. 12

shows a known supply/recovery system of the cooling steam for rotor blades of a turbine.




The structure of the gas turbine rotor on the turbine side is completed by fastening a rotor tail end and a plurality of turbine disks.




To supply and recover the cooling steam to and from the blades embedded in the turbine disks, the rotor tail end is provided with a center hole to define a coaxial steam pipe.




The rotor tail end


100


is provided with a substantially circular disk portion


120


which defines an end disk and a substantially cylindrical hollow shaft portion


140


. A disk center hole


130


and a rotor tail end center hole


150


extend along the central axis. The disk portion


120


is provided with a plurality of through holes (not shown) which are spaced from one another in the circumferential direction at an equal distance. A plurality of rotor blade disks (not shown) of the turbine are arranged in front of the disk portion


120


and, thereafter, turbine spindle bolts (not shown) are inserted in the through holes and fastened by nuts to form a rotor assembly in which the rotor blade disks (not shown) are supported and rotated together.




The disk center hole


130


of the rotor is provided with a steam passage member


200


welded thereto, through which the rotor blade cooling steam is supplied. A passage to recover the steam for cooling the rotor blade is defined between the inner surface of the central hole


150


of the rotor tail end extending from the rear end of the end disk of the rotor into the shaft portion


140


of the rotor and the steam passage member, so that the steam used to cool the rotor blades by means of an appropriate cooling device (not shown) can be recovered.




The connection between the rotating rotor tail end


100


and the stationary part is established as follows. For the inner tube, the steam passage member


200


is connected to a stationary inner steam pipe


290


through a seal fin (labyrinth seal)


230


. Thereafter, a stationary short steam pipe


270


and an outer stationary steam pipe


280


are connected to the end of the rotor tail end


100


through a seal fin (labyrinth seal)


220


. The seal fins


220


and


230


are connected to a leakage steam recovery instrument (not shown).




The rotor assembly thus obtained is rotatably supported at the rotor tail end


100


thereof by a bearing


240


. The rotor blade cooling steam is produced by heating pressurized steam whose saturation temperature is approximately 140° C. to 400° C. or more, and is supplied through the passageway defined by the center hole of the rotor. Consequently, the rotor is heated to the saturation temperature of the cooling steam. However, in general, the tail end at which the bearing is provided is cooled by the lubricant to 100° C. or less than 100° C., so that thermal deformation of the tail end occurs due to a temperature difference between the central hole and the tail end.




The preferred embodiments of the present invention will be discussed below with reference to the drawings.





FIG. 1

shows a sectional view of a half of a tail end


10


of a rotor assembly of a gas turbine (which will be referred to merely as a rotator tail end), according to an embodiment of the invention. In the present specification, the compressor side of the gas turbine is referred to as a front side (left side in

FIG. 1

) and the expansion device side is referred to as a rear side (right side in FIG.


1


).




The rotor tail end


10


includes an end disk


12


in the form of a substantially circular disk having a disk center hole


13


and a substantially cylindrical hollow shaft portion


14


. A steam passage member


20


for supplying cooling steam is welded to the disk center hole


13


. Moreover, the end disk


12


is provided with a plurality of through holes


12




b


(not shown) which are spaced at an equal distance in the circumferential direction about the center axis O in the longitudinal direction of the rotor assembly. Turbine spindle bolts (not shown) are inserted in the through holes


12




b


while the end disk


12


is in contact at its front end surface


12




a


with another disk (not shown) and the turbine spindle bolts are fastened by nuts (not shown), so that a rotor assembly which rotates as a unit, while supporting turbine rotor blades (not shown) is formed.




The rotor assembly constructed as above is rotatably supported at the rotor tail end


10


by a bearing


24


. The bearing


24


is comprised of a bearing pad


24




a,


and seal portions


26


provided on opposite sides of the bearing pad


24




a.


As is well known in the art of the gas turbine, the bearing


24


forms a journal bearing. The seal portions


26


include brackets


26




a


which are adapted to mount seal members


26




c


to the bearing pad


24




a.






The rotor tail end


10


is provided with a rotor tail end center hole


15


which is coaxial with the disk center hole


13


and whose diameter is greater than the diameter of the disk center hole


13


. A cylindrical thermal sleeve


16


is inserted in the rotor tail end center hole


15


. The front end of the thermal sleeve


16


(left end in

FIG. 1

) is welded to the rotor tail end center hole


15


and the rear end (right end in

FIG. 1

) is welded to the rear end of the shaft portion


14


. The outer diameter of the thermal sleeve


16


is smaller than the inner diameter of the rotor tail end center hole


15


and a thermal insulation gas layer


18


is formed therebetween. Preferably, the thermal insulation gas layer


18


is filled with dry gas or inert gas such as air or argon.




The thermal sleeve


16


is provided on its rear end with a bent portion


16




a


which is adapted to absorb the thermal stress and in particular the compression stress when a temperature difference is caused between the shaft portion


14


and the thermal sleeve


16


whose temperature is increased in accordance with the operation of the gas turbine. More preferably, the thermal sleeve


16


is welded to the shaft portion


14


while the thermal sleeve is tensed in the axial direction so that a pre-tension is applied thereto. Consequently, when a temperature difference is caused between the thermal sleeve


16


and the shaft portion


14


, in accordance with operation of the gas turbine, the compression stress can be reduced.




In the illustrated embodiment, the thermal sleeve


16


is inserted between the steam passage member


20


and the shaft portion


14


so that the thermal insulation gas layer


18


is formed between the thermal sleeve


16


and the inner surface of the rotor tail end center hole


15


of the shaft portion


14


. Consequently, when the gas turbine operates and the cooling steam for cooling the turbine rotor blades flows, the heat transfer to the shaft portion


14


is restricted, thus resulting in no or little thermal deformation of the shaft portion


14


.




Moreover, if a thermal expansion difference occurs due to the temperature difference between the thermal sleeve


16


and the shaft portion


14


by the steam passing in the steam passage member


20


during the operation of the turbine, since the thermal sleeve


16


is welded to the shaft portion


14


with a pre-tension, the thermal stress caused in the thermal sleeve


16


is reduced and thus the deformation thereof can be prevented. Moreover, since the thermal sleeve


16


is provided with the bent portion


16




a


at the rear end thereof, the thermal stress which cannot be absorbed by the application of the pre-tension can be absorbed by the deformation of the bent portion


16




a.


Thus, deformation of the cylindrical portion of the thermal sleeve


16


can be avoided. Moreover, the thermal insulation gas layer


18


is isolated gas-tightly and liquid-tightly from the outside, so that no steam can enter from the outside. Moreover, since the thermal insulation gas layer


18


is filled with a dry gas, no drain due to the condensation of the steam occurs even if the temperature drops during the stoppage of the gas turbine.





FIGS. 2 and 3

shows a second embodiment of the invention.




The rotor tail end


10


according to the second embodiment of the invention is comprised of a substantially circular disk portion


12


which forms an end disk and a substantially cylindrical hollow shaft portion


14


. A disk center hole


13


of a rotor and a rotor tail end center hole


15


are also formed in the rotor tail end along the longitudinal center axis O. The rotor tail end center hole


15


is coaxial to the disk center hole


13


and has a diameter greater than the diameter of the disk center hole


13


. Like the end disk


12


in the first embodiment, the disk portion


12


is provided with a plurality of through holes (not shown) which are spaced at an equal distance in the circumferential direction about the center axis O. Turbine spindle bolts (not shown) are inserted in the through holes while the disk portion


12


is in contact at its front end surface


12




a


with another disk (not shown) and the turbine spindle bolts are fastened by nuts (not shown), so that a rotor assembly which supports the turbine rotor blades (not shown) and rotates together therewith is formed. A steam passage member


20


is provided in the rotor disk center hole


13


to form a passage for the steam for cooling the turbine rotor blades. The inner surface of the rotor tail end center hole


15


of the shaft portion


14


of the rotor and the steam passage member


20


define therebetween a passage for recovering the steam for cooling the turbine rotor blades. The rotor assembly constructed as above is rotatably supported at the tail end


10


by the bearing


24


as in the first embodiment.




The shaft portion


14


is provided with a plurality of shaft portion cooling air passages comprised of radially extending cooling air inlet passages


31




a,


axially extending main air passages


31




b,


and radially extending cooling air outlet passages


31




c.


The shaft portion cooling air passages are spaced at an equal distance in the circumferential direction about the center axis O. The main air passages


31




b


can be formed, for example, by drilling the rotor at the end thereof to form axially extending blind holes and thereafter closing the open ends of the blind holes by welds


31




d.






A cooling air introduction device


32


is provided to face the cooling air inlet passages


31




a.


The cooling air introduction device


32


is comprised of an air introduction passage


32




a


provided on a stationary part of the gas turbine, such as a casing (not shown), and a seal portion


32




b


provided on the inner circumferential surface of the air introduction portion


32




a.


The air introduction portion


32




a


and the seal portion


32




b


are respectively provided with air passages


32




c


and


32




d


which are connected to the cooling air inlet passages


31




a


and which are spaced at an equal distance in the circumferential direction, so that the cooling air supplied from the cooling air supply source (not shown) can be introduced into the cooling air inlet passages


31




a.






Likewise, a cooling air discharge device


33


is provided to face the cooling air outlet passages


31




c.


The cooling air discharge device


33


is comprised of an air discharge portions


33




a


provided on the stationary part of the gas turbine, such as the casing (not shown), and a seal portion


33




b


provided on the inner circumferential surface of the air discharge portion


33




a.


The air discharge portion


33




a


and the seal portion


33




b


are respectively provided with a plurality of air passages


33




c


and


33




d


which are connected to the cooling air discharge passages


31




c


and which are spaced at an equal distance in the circumferential direction. The air from the cooling air introduction device


32


is fed to a plurality of shaft portion cooling air passages


31




a,




31




b


and


31




c


to cool the rotor tail end


10


and is discharged to the outside of the gas turbine.




In the illustrated embodiment, since the shaft portion


14


is provided with a plurality of shaft portion cooling air passages


31




a,




31




b


and


31




c


in which the cooling air passes, when the turbine rotor blade cooling steam flows in the steam passage member


20


in accordance with the operation of the gas turbine, the shaft portion


14


is cooled at the portion thereof in the vicinity of the surface by the cooling air which passes in the shaft portion cooling air passages


31




a,




31




b


and


31




c


and, thus, a thermal deformation of the shaft portion


14


can be minimized or restricted.




A third embodiment of the invention is shown in

FIGS. 4 and 5

.




In the second embodiment mentioned above, a plurality of shaft portion cooling air passages


31




a,




31




b


and


31




c


are formed by directly drilling the shaft portion


14


. In the third embodiment, however, the shaft portion cooling air passages are formed between the outer peripheral surface of the shaft body portion and the sleeve by fitting a sleeve on an outer surface of the shaft body portion of the rotor tail end.




Referring to

FIGS. 4 and 5

, the rotor tail end


10


of the third embodiment is comprised of a substantially circular disk portion


12


which defines an end disk, a substantially cylindrical hollow shaft body portion


14


, and a sleeve


17


which is fitted on the shaft body portion


14


. The tail end center hole


15


of the rotor is formed to extend along the longitudinal center axis O. Like the previous embodiments, a rotor assembly is formed and is rotatably supported by a bearing


24


similar to that in the previous embodiments at the rotor tail end


10


. Namely, the shaft body portion


14


and the sleeve


17


fitted thereon define the shaft portion in the previous embodiments.




The sleeve


17


is comprised of a substantially cylindrical member having an inner peripheral surface


17




a


having an inner diameter equal to the diameter of the shaft portion


14


, and an outer peripheral surface


17




b


having an outer diameter equal to shaft portion of the rotor assembly which is rotatably supported by the bearing


24


. The inner peripheral surface


17




a


is provided with a plurality of axially extending semi-circular grooves


17




c.


The sleeve


17


is fitted on the outer peripheral surface of the shaft body portion


14


and, thereafter, the annular end plate


17




d


is secured to the end of the shaft body portion


14


by means of bolts


17




e.


The end plate


17




d


is provided with a plurality of cooling air outlet passages


31




c


which can be connected to main air passages


17




f


formed between the outer peripheral surface of the shaft body portion


14


and the grooves


17




c


of the sleeve


17


, when assembled as shown in FIG.


4


. The shaft portion


14


is provided with a plurality of cooling air inlet passages


31




a


in the vicinity of the proximal end thereof, which can be connected to the main air passages


17




f.


The cooling air inlet passages


31




a,


the main air passages


17




f


and the cooling air outlet passages


31




c


form a plurality of shaft portion cooling air passages. The shaft portion cooling air passages


31




a,




17




f,


and


31




c


are spaced at an equal distance in the circumferential direction with respect to the center axis O.




Like the second embodiment, a cooling air introduction device


32


is provided to face the cooling air inlet passages


31




a


and a cooling air discharge device


33


is provided to face the cooling air outlet passages


31




c.


The air from the cooling air introduction device


32


is fed to the shaft portion cooling air passages


31




a,




17




f


and


31




c


to cool the rotor tail end


10


and is discharged to the outside of the gas turbine.




In this embodiment, since the shaft portion cooling air passages


31




a,




17




f


and


31




c


in which the cooling air can be passed are formed between the shaft body portion


14


and the sleeve


17


, the sleeve


17


which forms a part of the shaft portion of the rotor tail end is cooled when the rotor blade cooling steam is fed in the steam passage member


20


in accordance with the operation of the gas turbine. Consequently, the thermal deformation of the shaft portion is minimized or restricted.





FIGS. 6 through 8

shows a fourth embodiment of the present invention.




In

FIG. 6

, the rotor tail end


10


of the fourth embodiment is comprised of a substantially circular disk portion


12


which defines an end disk, and a substantially cylindrical hollow shaft portion


14


. The disk center hole


13


of the rotor and the rotor tail end center hole


15


are formed to extend along the longitudinal center axis O. The rotor tail end center hole


15


is coaxial to the disk center hole


13


and has a diameter greater than the diameter of the disk center hole


13


. Like the end disk


12


in the first embodiment, the disk portion


12


is provided with a plurality of through holes (not shown) which are spaced at an equal distance in the circumferential direction about the center axis O. Turbine spindle bolts (not shown) are inserted in the through holes while the disk portion


12


is in contact at its front end surface


12




a


with another disk (not shown), the turbine spindle bolts are fastened by nuts (not shown), so that a rotor assembly which supports the turbine rotor blades (not shown) and rotates together therewith is formed. A steam passage member


20


is provided in the rotor disk center hole


13


to form a passage for the steam for cooling the turbine rotor blades. The inner surface of the rotor tail end center hole


15


of the shaft portion


14


of the rotor and the steam passage member define therebetween a passage for recovering the steam for cooling the turbine rotor blades. The rotor assembly constructed as above is rotatably supported at the tail end


10


by the bearing


24


.




The bearing


24


in this embodiment is comprised of a bearing pad


24




a


and seal portions


26


provided on opposite sides of the bearing pad


24




a.


The seal portions


26


include seal members


26




c


and brackets to mount the seal members


26




c


to the bearing pad


24




a.


The brackets include radial securing portions


26




a


mounted to the bearing pad


24




a


and ledges


26




b


connected to the radial securing portions


26




a,


so that the brackets are L-shaped in a cross section. In this embodiment, the seal members


26




c


are greater in the width, i.e. in the size in the axial direction, than those of the embodiments illustrated in

FIGS. 1 through 5

. Accordingly, the brackets of the bearing


24


are provided with the ledges


26




b


which extend in the axial direction, unlike the previous embodiments shown in

FIGS. 1 through 5

.




As mentioned above, in a journal bearing which is commonly used in a gas turbine, the bearing pad is provided with an oil passage (not shown) extending therethrough in the radial direction, so that a lubricant is supplied through the oil passage to lubricate the gap between the shaft portion of the rotor assembly and the bearing and to cool the gap between the shaft portion and the bearing pad. The seal member reduces the leakage of lubricant from the gap between the shaft portion and the bearing pad, so that the lubrication between the shaft portion and the bearing pad can be promoted. However, in a conventional journal bearing, the width of the seal portion in the axial direction is insufficient and, hence, the distribution of temperature T of the outer surface of the shaft portion in the axial direction exhibits a constant low temperature TL at the center area “a” of the bearing pad which is cooled by the lubricant and forms asymptotes approaching a constant high temperature TH symmetrically on both sides of the area “a” in the axial directions away from the center area “a”. Consequently, a thermal deformation analogous to the temperature distribution shown in

FIG. 7

occurs in the shaft portion, so that the gap between the shaft portion and the bearing pad is made excessively narrow or the shaft portion and the bearing pad interfere with or touch each other.




In the fourth embodiment of the present invention, the seal members


26




c


which are greater in width in the axial direction than the seal members of the prior art is used to resolve the problems of the prior art mentioned above. Namely, the seal members


26




c


must be long enough to maintain the surface temperature of the shaft portion


14


at the constant low temperature TL, in the area of the axial length L


0


of the bearing pad


24




a,


i.e., in the surface area of the shaft portion


14


opposed to the bearing pad. With the seal members having the width in the axial direction so as to cool the shaft portion


14


over the broader range in the axial direction than the prior art, it is possible to prevent the gap between the shaft portion


14


and the bearing pad


24




a


from being made excessively small, or it is possible to reduce the thermal deformation of the shaft portion


14


, whereby no interference or no contact of the shaft portion with the bearing pad


24




a


takes place.




A fifth embodiment of the present invention will be discussed below with reference to FIG.


9


.




The rotor tail end


10


is comprised of a substantially circular end disk


12


having a disk center hole


13


, and a substantially cylindrical hollow shaft portion


14


. A cooling steam supply passage member


20


is welded to the disk center hole


13


. The end disk


12


is provided with a plurality of through holes


12




b


(not shown) which are spaced at an equal distance in the circumferential direction about the longitudinal center axis O of the rotor assembly. Turbine spindle bolts (not shown) are inserted in the through holes while the disk portion


12


is in contact at its front end surface


12




a


with another disk (not shown), and the turbine spindle bolts are fastened by nuts (not shown), so that a rotor assembly which supports the turbine rotor blades (not shown) and rotates together therewith is formed.




The rotor assembly thus obtained is rotatably supported at the tail end


10


by the bearing


24


. The bearing


24


is comprised of a bearing pad


24




a


and seal portions


26


on opposite sides of the bearing pad


24




a.


The bearing


24


forms a journal bearing as is well known in the field of gas turbines. The seal portions


26


include brackets


26




a


to mount the seal members


26




c


to the bearing pad


24




a.






A cylindrical thermal sleeve


16


is inserted in the rotor tail end center hole


15


of the rotor tail end


10


. The rotor tail end center hole


15


is coaxial to the disk center hole


13


and has a diameter greater than the diameter of the disk center hole


13


. The front end of the thermal sleeve


16


(left end in

FIG. 9

) is welded to the rotor tail end center hole


15


and the rear end (right end in

FIG. 9

) thereof is welded to the rear end of the shaft portion


14


. The thermal sleeve


16


has an outer diameter smaller than the inner diameter of the rotor tail end center hole


15


of the shaft portion


14


, so that a thermal insulation gas layer


18


is formed therebetween.




The thermal sleeve


16


is provided on its rear end with a bent portion


16




a


which is adapted to absorb the thermal stress and in particular the compression stress when a temperature difference is caused between the shaft portion


14


and the thermal sleeve


16


whose temperature is increased in accordance with the operation of the gas turbine. More preferably, the thermal sleeve


16


is welded to the shaft portion


14


while the thermal sleeve is tensed in the axial direction so that a pre-tension is applied thereto. Consequently, when a temperature difference is caused between the thermal sleeve


16


and the shaft portion


14


, in accordance with the gas turbine, the compression stress can be reduced.




The shaft portion


14


is provided with a plurality of shaft portion cooling air passages which are comprised of radially extending cooling air inlet passages


31




a


and cooling air outlet passages


31




c


and which are connected to the thermal insulation gas layer


18


to form a cooling air passageway.




A cooling air introduction device


32


is provided to face the cooling air inlet passages


31




a.


The cooling air introduction device


32


is comprised of an air introduction portion


32




a


provided on a stationary part of the gas turbine, such as a casing (not shown), and a seal member


32




b


provided on the inner surface of the air introduction portion


32




a.


The air introduction portion


32




a


and the seal member


32




b


are respectively provided with a plurality of air passages


32




c


and


32




d


which are connected to the cooling air inlet passages


31




a


and which are spaced at an equal distance in the circumferential direction, so that the cooling air supplied from the cooling air supply source (not shown) can be introduced into the cooling air inlet passages


31




a.






Likewise, a cooling air discharge device


33


is provided to face the cooling air outlet passages


31




c.


The cooling air discharge device


33


is comprised of an air discharge portion


33




a


provided on the stationary part of the gas turbine, such as the casing, and a seal member


33




b


provided on the inner surface of the air discharge portion


33




a.


The air discharge portion


33




a


and the seal portion


33




b


are respectively provided with a plurality of air passages


33




c


and


33




d


which are connected to the cooling air outlet passages


31




c


and which are spaced at an equal distance in the circumferential direction. The air from the cooling air introduction device


32


is fed to the shaft portion cooling air passages


31




a,




18


and


31




c


to cool the rotor tail end


10


and is discharged to the outside of the gas turbine.




In the illustrated embodiment, since the shaft portion


14


is provided with a plurality of shaft portion cooling air passages


31




a,




18


and


31




c


in which the cooling air can be passed, when the turbine rotor blade cooling steam flows in the steam passage member


20


in accordance with the operation of the gas turbine, the bearing region of the shaft portion


14


is cooled by the cooling air which passes in the shaft portion cooling air passages


31




a,




18


and


31




c


and, thus, a thermal deformation of the shaft portion


14


can be reduced or restricted.




A sixth embodiment of the present invention will be discussed below with reference to FIG.


10


.




The rotor tail end


10


is comprised of a substantially circular end disk


12


having a disk center hole


13


, and a substantially cylindrical hollow shaft portion


14


. A cooling steam supply passage member


20


is welded to the disk center hole


13


. The end disk


12


is provided with a plurality of through holes


12




b


(not shown) which are spaced at an equal distance in the circumferential direction about the longitudinal center axis O of the rotor assembly. Turbine spindle bolts (not shown) are inserted in the through holes while the disk portion


12


is in contact at its front end surface


12




a


with another disk (not shown), and the turbine spindle bolts are fastened by nuts (not shown), so that a rotor assembly which supports the turbine rotor blades (not shown) and rotates together therewith is formed.




The rotor assembly thus obtained is rotatably supported at the tail end


10


by the bearing


24


. The bearing


24


is comprised of a bearing pad


24




a


and seal portions


26


on opposite sides of the bearing pad


24




a.


The bearing


24


forms a journal bearing as is well known in the field of gas turbines. The seal portions


26


are provided with brackets


26




a


to mount the seal members


26




c


to the bearing pad


24




a.






A cylindrical thermal sleeve


16


is inserted in the rotor tail end center hole


15


of the rotor tail end


10


. The rotor tail end center hole


15


is coaxial to the disk center hole


13


and has a diameter greater than the diameter of the disk center hole


13


. The front end of the thermal sleeve


16


(left end in

FIG. 10

) is welded to the rotor tail end center hole


15


and the rear end (right end in

FIG. 10

) thereof is welded to the rear end of the shaft portion


14


. The thermal sleeve


16


has an outer diameter smaller than the inner diameter of the rotor tail end center hole


15


of the shaft portion


14


, so that a thermal insulation gas layer


18


is formed therebetween.




The thermal sleeve


16


is provided on its rear end with a bellows


16




b


which is adapted to absorb the thermal stress and in particular the compression stress when a temperature difference is caused between the shaft portion


14


and the thermal sleeve


16


whose temperature is increased in accordance with the operation of the gas turbine. The bellows


16




b


is provided on its ends with flanges which are in turn provided with holes in which mounting bolts are inserted to mount the bellows


16




b


to the thermal sleeve


16


and the shaft. Thus, the bellows can be easily manufactured and the maintenance of the bellows can be facilitated. Moreover, as can be seen in the drawings, seal members, such as O-rings or C-seal members (not shown) are provided between the flanges of the bellows and the thermal sleeve and between the flanges of the bellows and the shaft to more reliably insulate the thermal insulation gas layer


18


in the gas-tightly and liquid-tightly from the outside.




A seventh embodiment of the present invention will be discussed below with reference to FIG.


11


.




The rotor tail end


10


is comprised of a substantially circular end disk


12


having a disk center hole


13


, and a substantially cylindrical hollow shaft portion


14


. A cooling steam supply passage member


20


is welded to the disk center hole


13


. The end disk


12


is provided with a plurality of through holes


12




b


(not shown) which are spaced at an equal distance in the circumferential direction about the longitudinal center axis O of the rotor assembly. Turbine spindle bolts (not shown) are inserted in the through holes while the disk portion


12


is in contact at its front end surface


12




a


with another disk (not shown), and the turbine spindle bolts are fastened by nuts (not shown), so that a rotor assembly which supports the turbine rotor blades (not shown) and rotates together therewith is formed.




The rotor assembly thus obtained is rotatably supported at the tail end


10


by the bearing


24


. The bearing


24


is comprised of a bearing pad


24




a


and seal portions


26


on opposite sides of the bearing pad


24




a.


The bearing


24


forms a journal bearing as is well known in the field of gas turbines. The seal portions


26


are provided with brackets


26




a


to mount the seal members


26




c


to the bearing pad


24




a.






An outer steam pipe


19


is inserted in the rotor tail end center hole


15


of the rotor tail end


10


. The rotor tail end center hole


15


is coaxial to the disk center hole


13


and has a diameter greater than the diameter of the disk center hole


13


. The front end of the outer steam pipe


19


(left end in

FIG. 11

) is welded to the rotor tail end center hole


15


and the rear end (right end in

FIG. 11

) thereof is inserted through a seal fin (outer pipe)


22


provided on a stationary steam pipe (outer pipe)


28


. Like the prior art (FIG.


12


), the left end of the steam passage member


20


is welded to the disk center hole


13


of the end disk


12


and the right end thereof is inserted in the inner stationary steam pipe


29


through a seal fin (inner pipe)


23


. The steam passage member


20


and the outer steam pipe


19


are rotatable and extendable due to the seal fins


22


and


23


. The leakage of steam from the seal fins


22


and


23


is recovered by recovery equipment (not shown). In this embodiment, the outer steam pipe


19


serves as a thermal sleeve to restrict the overheating of the shaft portion


14


of the rotor and the extension and contraction due to the temperature difference of the steam pipes is absorbed by the seal fins.




Although the invention has been shown and described with exemplary embodiments thereof, it should be understood by those skilled in the art that the foregoing and various other changes, omissions and additions may be made therein and thereto without departing from the spirit and the scope of the invention.



Claims
  • 1. A shaft structure of a rotor tail end of a gas turbine, comprising:a rotor assembly of the gas turbine having a center axis; rotor blades of the gas turbine; a steam passage extending along the center axis for supplying and recovering a steam for cooling the rotor blades; a rotor tail end in which a center hole of the rotor tail end coaxial to the center axis of the steam passage is formed; a thermal sleeve provided between the steam passage and an inner surface of the center hole of the rotor tail end; and a thermal insulation gas layer formed between the inner surface of the center hole of the rotor tail end and the thermal sleeve; the thermal insulation gas layer being isolated gas-tightly and liquid-tightly from the outside, wherein said thermal sleeve is in the form of a substantially circular cylinder which is welded at its one end to an end disk of the gas turbine and welded at the other end to a shaft portion of the rotor tail end, said thermal sleeve being provided with a bent portion in the vicinity of the end thereof welded to the shaft portion of the rotor tail end, so that the bent portion reduces a thermal stress due to a thermal expansion of the thermal sleeve.
  • 2. A shaft structure of a rotor tail end of a gas turbine according to claim 1, wherein a pre-tension is applied to the thermal sleeve when the latter is mounted to the end disk or the shaft portion.
  • 3. A shaft structure of a rotor tail end of a gas turbine, comprising:a rotor assembly of the gas turbine having a center axis; rotor blades of the gas turbine; a steam passage extending along the center axis for supplying and recovering a steam for cooling the rotor blades; a plurality of shaft portion cooling air passages formed between the steam passage and an outer surface of a shaft portion of the rotor tail end; an air introduction portion provided on a stationary part of the gas turbine; and a seal member provided on an inner surface of the air introduction portion.
  • 4. A shaft structure of a rotor tail end of a gas turbine according to claim 3, wherein said shaft portion cooling air passages are at least partly formed directly in the shaft portion.
  • 5. A shaft structure of a rotor tail end of a gas turbine according to claim 3 or 4, wherein said shaft portion comprises a shaft body portion which surrounds the steam passage, and a sleeve fitted on an outer surface of the shaft body portion, and wherein said shaft portion cooling air passages includes a main air passage which is formed at least partly between the shaft body portion and the sleeve.
  • 6. A bearing structure for bearing a shaft portion of a rotor tail end of a gas turbine, comprising:a rotor assembly of the gas turbine having a center axis; rotor blades of the gas turbine; a steam passage extending along the center axis for supplying and recovering a steam for cooling the rotor blades; a bearing pad which forms a journal bearing; and seal portions provided on opposite sides of the bearing pad in an axial direction to prevent leakage of a lubricant for lubricating a space between the bearing pad and the shaft portion, a width of said seal portion in the axial direction being such that a surface temperature of the shaft portion of the rotor tail end is maintained below a predetermined temperature by the lubricant, within the width of the bearing pad in the axial direction.
  • 7. A shaft structure of a rotor tail end of a gas turbine, comprising:a rotor assembly of the gas turbine having a center axis; rotor blades of the gas turbine; a steam passage extending along the center axis for supplying and recovering a steam for cooling the rotor blades; a rotor tail end in which a center hole coaxial to the center axis of the steam passage is formed; a thermal sleeve provided between the steam passage and an inner surface of the center hole of the rotor tail end; a thermal insulation gas layer formed between the inner surface of the center hole of the rotor tail end and the thermal sleeve; an air introduction portion provided on a stationary part of the gas turbine; and a seal member provided on an inner surface of the air introduction portion, wherein cooling air is circulated from the outside into the thermal insulation gas layer.
  • 8. A shaft structure of a rotor tail end of a gas turbine, comprising:a rotor assembly of the gas turbine having a center axis; rotor blades of the gas turbine; a steam passage extending along the center axis for supplying and recovering a steam for cooling the rotor blades; a rotor tail end in which a center hole coaxial to the center axis of the steam passage is formed; a thermal sleeve provided between the steam passage and an inner surface of the center hole of the rotor tail end; and a thermal insulation gas layer formed between the inner surface of the center hole of the rotor tail end and the thermal sleeve; cooling air being circulated from the outside into the thermal insulation gas layer, wherein said thermal sleeve is in the form of a substantially circular cylinder which is welded at its one end to an end disk of the gas turbine and is welded at the other end to a shaft portion of the rotor tail end through a bellows which reduces a thermal stress due to a thermal expansion of the thermal sleeve.
  • 9. A shaft structure of a rotor tail end of a gas turbine, comprising:a rotor assembly of the gas turbine having a center axis; rotor blades of the gas turbine; a steam passage extending along the center axis for supplying and recovering a steam for cooling the rotor blades; a first labyrinth seal through which the steam passage is connected to a stationary inner steam pipe; a rotor tail end in which a center hole coaxial to the center axis of the steam passage is formed; a steam pipe provided in the center hole of the rotor tail end; a thermal insulation gas layer formed between an inner surface of the center hole of the rotor tail end and the steam pipe; and a second labyrinth seal through which the steam pipe is connected to a stationary outer steam pipe.
  • 10. A shaft structure of a rotor tail end of a gas turbine, comprising:a rotor assembly of the gas turbine having a center axis; rotor blades of the gas turbine; a steam passage extending along the center axis for supplying and recovering a steam for cooling the rotor blades; a rotor tail end in which a center hole of the rotor tail end coaxial to the center axis of the steam passage is formed; a thermal sleeve provided between the steam passage and an inner surface of the center hole of the rotor tail end; and a thermal insulation gas layer formed between the inner surface of the center hole of the rotor tail end and the thermal sleeve; the thermal insulation gas layer being isolated gas-tightly and liquid-tightly from the outside, wherein said thermal sleeve is in the form of a substantially circular cylinder which is welded at its one end to an end disk of the gas turbine and is welded at the other end to a shaft portion of the rotor tail end through a bellows which reduces a thermal stress due to a thermal expansion of the thermal sleeve.
Priority Claims (1)
Number Date Country Kind
2000-292763 Sep 2000 JP
US Referenced Citations (2)
Number Name Date Kind
6293089 Sasaki Sep 2001 B1
6450758 Schmidt Sep 2002 B1
Foreign Referenced Citations (7)
Number Date Country
0 894 942 Feb 1999 EP
0 936 350 Aug 1999 EP
1 010 858 Jun 2000 EP
1 013 895 Jun 2000 EP
1 013 895 Jun 2000 EP
03253726 Dec 1991 JP
2000-192803 Jul 2000 JP