A turbine seal includes a first arcuate segment defining a flowpath boundary between combustion gases and air, and includes a radially outwardly extending rail at one end thereof. A second arcuate segment is disposed coaxially with the first segment for defining a continuation of the flowpath boundary, and has a radially extending face adjoining the rail. A leaf seal bridges the rail and the face for sealing leakage therebetween, and a plurality of pins extend through the leaf seal for providing mounting to the rail. Each pin includes a head and an opposite tip, with the pins being fixedly joined to the rail solely about the pin tips for freely supporting the pin heads in a cantilever without obstruction therearound for eliminating supporting tabs. A leaf spring is mounted on the pins between the heads and the leaf seal to pre-load the leaf seal against the rail and face to effect the sealing therebetween.

BACKGROUND OF THE INVENTION 
The present invention relates generally to gas turbine engines, and, more 
specifically, to turbine flowpath seals therein. 
A gas turbine engine includes a compressor for compressing air which is 
mixed with fuel and ignited in a combustor for generating hot combustion 
gases which flow downstream therefrom. The combustion gases flow through 
one or more turbine stages for extracting energy therefrom for powering 
the compressor and providing other useful work. 
A turbine stage includes a stationary turbine nozzle having a plurality of 
circumferentially spaced apart vanes extending radially between outer and 
inner bands which define a flowpath for channeling the combustion gases 
therethrough. Disposed downstream of a nozzle stage is a turbine rotor 
including a plurality of circumferentially spaced apart rotor blades 
extending radially outwardly from a rotor disk, and surrounded by an 
annular shroud which defines a portion of the radially outer flowpath for 
the combustion gases. The turbine nozzles and rotor shrouds are separately 
manufactured and assembled into position in the engine. Accordingly, gaps 
are necessarily provided therebetween for both assembly purposes as well 
as for accommodating differential thermal expansion and contraction during 
operation of the engine. 
The gaps between these stationary stator components must be suitably sealed 
for preventing leakage therethrough. In a typical high pressure turbine 
nozzle, a portion of the compressor air is bled therefrom and channeled 
through the nozzle vanes for cooling thereof. The use of bleed air reduces 
the overall efficiency of the engine and therefore is minimized whenever 
possible. The bleed air is at a relatively high pressure greater than the 
pressure of the combustion gases flowing through the turbine nozzle and 
therefore would leak into the exhaust flowpath without providing suitable 
seals between the stator components. 
A typical seal used in turbine flowpaths is a leaf seal. Leaf seals are 
typically arcuate and are disposed end to end around the circumference of 
the stator components. For example, the radially outer band of the turbine 
nozzle includes axially spaced apart forward and aft rails. These rails 
extend radially outwardly, with the aft rail abutting a complementary 
surface on the adjoining shroud or shroud hanger for providing a primary 
friction seal therewith. The leaf seal provides a secondary seal at this 
junction, and bridges a portion of the aft rail and the shroud hanger for 
example. 
In order to assemble and mount the leaf seals to the aft rail, each leaf 
seal typically includes mounting holes at opposite circumferential ends 
thereof through which are mounted corresponding mounting pins. 
Corresponding leaf springs are also used at respective ones of the 
mounting pins for preloading the loosely supported leaf seals against the 
aft rail and the shroud hanger. During operation when air pressure is 
developed outboard of the outer band, the air pressure provides a 
substantial loading force against the leaf seal for improving its sealing 
effectiveness with the aft rail and the shroud hanger. 
In order to support the leaf seals, leaf springs, and mounting pins, the 
outer band typically includes a plurality of circumferentially spaced 
apart, radially extending tabs spaced axially from the aft rail. The tabs 
include through holes aligned with corresponding holes in the aft rail, 
and the pins are inserted through the tabs and into the aft rail and then 
fixedly joined thereto by tack welding the heads of the pins to the 
corresponding tabs. In this way, the mounting pins are supported from both 
ends to the tabs and aft rail, and the leaf seals and leaf springs are 
trapped in the recess defined between the tabs and the aft rail. 
However, this mounting arrangement for the leaf seals is relatively complex 
and subject to damage during the assembly process in view of the 
relatively close quarters in this region. The leaf seals and springs are 
relatively small components, and the mounting tabs are therefore 
positioned relatively close to the aft rail which increases the difficulty 
of manufacturing these components. The aft rail and the tabs must be 
accurately machined to close tolerances, and the limited access provided 
due to their closeness increases the difficulty and cost of manufacturing. 
Furthermore, high temperature turbine nozzles are more commonly being 
formed of advanced superalloy metals, including single crystal metals. The 
integral tabs alter the basic shape of the band and further complicate the 
manufacture thereof. 
Accordingly, an improved leaf seal installation arrangement is desirable 
for simplifying the manufacture and assembly thereof, and eliminating 
extraneous components. 
SUMMARY OF THE INVENTION 
A turbine seal includes a first arcuate segment defining a flowpath 
boundary between combustion gases and air, and includes a radially 
outwardly extending rail at one end thereof. A second arcuate segment is 
disposed coaxially with the first segment for defining a continuation of 
the flowpath boundary, and has a radially extending face adjoining the 
rail. A leaf seal bridges the rail and the face for sealing leakage 
therebetween, and a plurality of pins extend through the leaf seal for 
providing mounting to the rail. Each pin includes a head and an opposite 
tip, with the pins being fixedly joined to the rail solely about the pin 
tips for freely supporting the pin heads in a cantilever without 
obstruction therearound for eliminating supporting tabs. A leaf spring is 
mounted on the pins between the heads and the leaf seal to pre-load the 
leaf seal against the rail and face to effect the sealing therebetween.

DESCRIPTION OF THE PREFERRED EMBODIMENT(S) 
Illustrated schematically in FIG. 1 is a portion of an exemplary aircraft 
turbofan gas turbine engine 10 which is axisymmetrical about a 
longitudinal or axial centerline axis 12. The engine 10 includes in serial 
flow communication a fan 14, multistage axial compressor 16, annular 
combustor 18, high pressure turbine nozzle 20, a single stage high 
pressure turbine rotor 22, and one or more stages of low pressure turbine 
nozzles and rotors 26. These components may take any conventional 
configuration, with the high pressure rotor 22 being suitably joined to 
the compressor 16 by a first shaft, and the low pressure rotor 26 being 
joined to the fan 14 by a second coaxial shaft. 
During operation, air flows downstream in turn through the fan 14 and 
compressor 16 and is pressurized therein and channeled to the combustor 18 
wherein it is suitably mixed with fuel and ignited for generating hot 
combustion gases 30 which flow downstream through the several turbine 
components which extract energy therefrom for powering both the fan 14 and 
the compressor 16. The various stator and rotor components of the turbines 
downstream from the combustor 18 define a flowpath which channels the hot 
combustion gases therethrough for discharge from the engine. 
A portion of the pressurized air 28 is suitably bled from the compressor 16 
to provide bleed or cooling air 28a which is suitably channeled to various 
components of the turbines for providing cooling thereof, such as cooling 
of the high pressure nozzle 20. The bleed air 28a channeled around and 
through the high pressure nozzle 20 is at a substantially higher pressure 
than that of the combustion gases 30 flowing therethrough during 
operation. 
Since the individual turbine components are separately manufactured and 
then assembled together in the engine 10, various joints or gaps are 
provided therebetween which must be suitably sealed for preventing leakage 
of the high pressure bleed air 28a into the combustion or exhaust 
flowpath. The use of bleed air for cooling turbine components necessary 
decreases the overall efficiency of the engine 10 and the use thereof is 
preferably minimized. It is desirable to provide suitable seals between 
the stationary or stator turbine components for reducing to a minimum the 
amount of cooling air leakage into the exhaust flowpath for increasing 
efficiency of the engine. 
In accordance with the present invention, improved turbine flowpath seals 
may be provided where desired between the various turbine stator 
components for sealing leakage of the cooling air 28a into the exhaust 
flowpath. In the exemplary engine illustrated in FIG. 1, one embodiment of 
a turbine flowpath seal is designated 32 and is located between the high 
pressure turbine nozzle 20 and the high pressure turbine rotor 22, with it 
being understood that the seal may be suitably used and adapted for any 
analogous sealing position within the engine 10, and in particular between 
the various turbine stator components thereof. 
More specifically, and referring to FIG. 2, the high pressure turbine 
nozzle 20 is illustrated in more particularity adjacent to the high 
pressure turbine rotor 22 in an exemplary configuration of the turbine 
seal 32. The turbine nozzle 20 includes an annular radially outer band 34, 
and a coaxial annular radially inner band 36 between which extend radially 
and are fixedly joined thereto a plurality of circumferentially spaced 
apart hollow stator vanes 38. The nozzle 20 may take any conventional 
configuration for channeling therethrough the combustion gases 30 received 
from the combustor 18. The inner surface of the outer band 34 and the 
outer surface of the inner band 36 define portions of flowpath boundaries 
for the combustion gases 30 which are channeled downstream to the turbine 
rotor 22. The rotor 22 may take any conventional form having a plurality 
of circumferentially spaced apart rotor blades 22a extending radially 
outwardly from a rotor disk for extracting energy from the gases 30 and 
powering the compressor 16. 
As discussed above, the cooling air 28a is suitably channeled around the 
nozzle 20 and flows radially inwardly through the individual vanes 38 for 
cooling thereof in a conventional manner. The cooling air 28a circulates 
around the outer surface of the outer band 34 and is at an elevated 
pressure (P.sup.+) compared to the lower pressure (P.sup.-) of the 
combustion gases 30 channeled through the nozzle 20. 
Adjoining the outer band 34 axially downstream therefrom is a stationary 
shroud assembly which may take any conventional form for continuing the 
outer flowpath boundary radially outwardly of the turbine blades 22a. In 
the exemplary embodiment illustrated in FIG. 2, a plurality of 
circumferentially adjoining arcuate turbine shrouds 40 are suitably 
supported from a plurality of circumferentially adjoining shroud hangers 
42, which in turn are supported from an annular outer casing 44 in a 
conventional arrangement using various forward and aft hooks and retention 
clips. The shroud 40 and hanger 42 are disposed coaxially with the turbine 
nozzle 20 for defining a radially outer flowpath boundary around the 
turbine blades 22a along which the combustion gases 30 flow from the 
nozzle 20. 
The nozzle 20 is typically formed in a plurality of circumferentially 
adjoining segments for reducing stress therein due to differential thermal 
expansion and contraction. The nozzle outer band 34 includes axially 
spaced apart forward and aft rails 46, 48 which extend radially and 
circumferentially therewith in an integral, cast configuration. 
The nozzle outer band 34 defines a first arcuate segment, with the radially 
inner surface of the outer band 34 defining an outer flowpath boundary 
between the combustion gases 30 inside or inboard thereof and the 
pressurized air 28a outside or outboard thereof. In the exemplary 
embodiment illustrated in FIG. 2, the turbine seal 32 is disposed at the 
aft rail 48 to seal against air leakage with the shroud hanger 42, which 
defines a second arcuate segment disposed coaxially with the outer band or 
first segment 34. In alternate embodiments, the individual shrouds 40 may 
be directly mounted to the outer casing 44, but in the exemplary 
embodiment illustrated in FIG. 2, the shrouds 40 are mounted to the shroud 
hangers 42, which in turn are mounted to the casing 44. 
Accordingly, the seal 32 may be configured for sealing either the turbine 
shroud 40 itself or its shroud hanger 42 as shown. The shroud hanger 42 
and the shroud 40 define an extension or continuation of the outer 
flowpath boundary of the outer band 34. The hanger 42 may have any 
suitable configuration and includes a radially extending forward face 50 
directly facing and adjoining the aft rail 48. 
The seal 32 is specifically configured for sealing the adjoining nozzle 
outer band 34 and shroud hanger 42 and is illustrated in more 
particularity in FIG. 3. The first and second arcuate segments defined by 
the outer band 34 and the shroud hanger 42 in this exemplary embodiment 
are sealed using a conventional arcuate leaf seal 52 which bridges the aft 
rail 48 and the forward face 50 for sealing leakage therebetween of the 
cooling air 28a outboard of the outer band 34. 
A plurality of mounting pins 54 extend through the leaf seal 52, with each 
pin 54 having an enlarged head 54a at a distal end thereof, and a smaller 
tip 54b at an opposite proximal end thereof, with a generally cylindrical 
shank 54c extending therebetween. The pins 54 are suitably fixedly joined 
to the aft rail 48 in accordance with the present invention solely about 
the pin tips 54b for freely supporting the pin heads 54a and shanks 54c in 
a cantilever fashion without obstruction therearound which would otherwise 
be provided by conventional mounting tabs (not shown) formed integrally 
with the outer band 34. 
A plurality of leaf springs 56 are mounted on respective ones of the pins 
54 between the pin heads 54a and the leaf seal 52 to bias or pre-load the 
leaf seal 52 against the aft rail 48 and forward face 50 to effect sealing 
therebetween. 
FIG. 4 illustrates the assembled flowpath seal 32 in a forward looking aft 
view. The leaf seals 52 and leaf springs 56 may take any conventional form 
and are typically suitable metal for the hot turbine environment of the 
engine, with the leaf seals 52 being arcuate segments which 
circumferentially adjoin each other around the circumference of the nozzle 
20. A pair of the mounting pins 54 is typically used for mounting the 
circumferentially opposite ends of the leaf seal 52 to the aft rail 48, 
with a corresponding pair of the leaf springs 56 mounted on the respective 
pins 54. 
As shown in FIG. 3, each leaf spring 56 is a generally partially folded 
member with a suitable U-configuration for being trapped between pin head 
54a and the leaf seal 52 in compression therebetween for biasing the leaf 
seal 52 against the aft rail 48 and forward face 50 of the shroud hanger 
42. The leaf seal 52 and leaf spring 56 have suitable apertures 
therethrough for loosely surrounding the pin shank 54c in a generally 
conventional configuration. 
However, in accordance with the present invention, the individual pins 54 
are mounted solely at their tips 54b to the aft rail 48 for eliminating 
the conventional tabs which would otherwise be required to support the pin 
heads. Eliminating these tabs as integral components of the outer band 34 
provides a substantially simplified and improved arrangement. By 
eliminating the tabs, the outer band 34 itself is simpler, and therefore 
may be more simply manufactured using casting techniques, and improving 
the ability to form single crystal alloys therein. Elimination of the tabs 
removes all obstructions on the forward side of the aft rail 48 for 
improving the required accurate machining thereof during manufacture. 
However, the pins 54 must nevertheless be suitably mounted to the aft rail 
48 in accordance with the present invention as further described 
hereinbelow. More specifically, the aft rail 48 illustrated in FIG. 3 
includes first and second axially opposite sides 48a,b having a plurality 
of pin mounting holes 58 extending therebetween and completely through the 
aft rail 48. Corresponding ones of the pin tips 54b are disposed in 
respective ones of the mounting holes 58 and are fixedly joined thereto. 
The pin heads 54a and leaf seals 52 are disposed adjacent to the rail first 
side 48a which faces forwardly in the upstream direction, and the pin tips 
54b extend through the rail to the rail second side 48b which faces in the 
aft, downstream direction. The pin tips 54b are therefore readily 
accessible in the aft side of the rail 48 and may be conveniently fixedly 
joined thereto using conventional brazing, or tack welds 60 for example. 
The pin tips 54b may be slightly recessed in the rail second side 48b so 
that the tack welds 60 do not undesirably project outwardly from the rail 
second side 48b. Brazing or welding of the pin tips 54b inside the 
mounting holes 58 provides an effective metallurgical bond with the aft 
rail 48 which cannot inadvertently separate during operation. 
The pin mounting holes 58 are preferably complementary in shape to the pin 
tips 54b in a suitably tight assembly therewith with relatively small 
clearances therebetween. In this way, the individual pins 54 may be 
securely attached to the aft rail 48 solely at their tip ends leaving the 
remainder of the pins 54 freely supported in a cantilever fashion for 
eliminating the need for a supporting tab at the head end of the pins 54. 
Since the leaf springs 56 are preferably slightly compressed when assembled 
to provide a suitable pre-load on the leaf seals 52, it is desirable to 
accurately position the pin heads 54a at a predetermined axial distance 
from the rail first side 48a. This is preferably accomplished by providing 
each of the pins 54 with a stepped shoulder 54d between the pin head 54a 
and the pin tip 54b for axially abutting the rail 48 around the mounting 
hole 58. The shoulder 54d is located adjacent to the pin tip 54b and may 
be created by simply forming the pin tip 54b with a suitably smaller outer 
diameter than the diameter of the pin shank 54c. The pin shoulder 54d 
abuts the aft rail 48 for maintaining the predetermined or fixed axial 
distance between the pin head 54a and the rail 48, for in turn maintaining 
a fixed compression of the leaf spring 56 to control pre-load on the leaf 
seal 52. The leaf seal 52 engages the aft rail 48, with the leaf spring 56 
being slightly compressed between the aft side of the pin head 54a and the 
forward side of the leaf seal 52. 
The pin shoulder 54d may engage the aft rail 48 in various configurations. 
For example, FIG. 3 illustrates that each of the mounting holes 58 
includes a step or counterbore extending inwardly from the rail first side 
48a toward the second side 48b for complementarily receiving the pin 
shoulder 54d. In this way, the pin shoulder 54d is disposed inside the aft 
rail 48, and the larger diameter pin shank 54c is therefore more rigidly 
secured to the aft rail 48 in a cantilever fashion. 
Alternatively, FIG. 5 illustrates another embodiment wherein the mounting 
holes 58 are fully cylindrical between the rail first and second sides 
48a,b with a common diameter, and the pin shoulders 54d axially abut the 
rail first side 48a. This avoids the additional step of forming the 
counterbore in the mounting hole 58 while still accurately positioning the 
head of the pin relative to the aft rail 48 for preferably compressing the 
leaf spring 56. 
Referring again to FIGS. 3 and 4, the aft rail 48 further includes a 
circumferentially extending first arcuate seat 62 at the radially outer, 
outboard end thereof on the rail first side 48a for seating thereagainst 
an intermediate portion of the leaf seal 52 in line contact. As shown in 
FIG. 3, an arcuate pad 64 is disposed axially oppositely the first seat 62 
integral with the rail second side 48b at the outboard end radially above 
the mounting holes 58. 
Correspondingly, the hanger face 50 includes an outboard portion on an 
integral lip 42a which defines a second arcuate seat 66 which receives in 
axially abutting contact therewith an outboard portion of the leaf seal 52 
for seating thereagainst in line contact around the circumference of the 
hanger 42. Accordingly, the leaf seal 52 frictionally engages and provides 
a secondary seal at the first and second seats 62, 66 to seal air leakage 
between the aft rail 48 and the hanger 42. 
An inboard portion of the hanger forward face 50 below the lip 42a defines 
a flat radially extending land which receives in abutting contact 
therewith the rail pad 64 to provide a primary friction seal thereat. The 
rail pad 64 extends circumferentially for providing the primary seal 
around the circumference of the aft rail 48 and can accommodate 
differential radial movement between the aft rail 48 and the hanger 42. 
The rail pad 64 suitably projects axially aft of the pin mounting holes 58 
above the inboard portion of the rail second side 48b to provide a 
suitable hinge for accommodating skewing of the components while 
maintaining an effective primary seal along the pads 64. 
In this way, the rail pad 64 and cooperating forward face 50 of the shroud 
hanger 42 provide primary sealing between these components, with the leaf 
seal 52 being mounted in an improved arrangement for providing a secondary 
seal between these components. The mounting arrangement is relatively 
simple yet eliminates the previously used integral mounting tabs extending 
from the outer band 34 for enjoying the several benefits described above. 
Although the improved flowpath seal 32 has been specifically described with 
respect to sealing the outboard aft end of the turbine nozzle 20 with the 
adjoining shroud 40 and shroud hanger 42, it may be suitably located and 
adapted for sealing between any adjacent stator components in the turbine 
section of the engine 10. Leaf seals are commonly found in turbines in 
high pressure and low pressure turbine sections between the stationary 
turbine nozzles and blade shrouds and hangers. The improved flowpath seal 
32 may therefore be used to replace any similarly configured leaf seal 
otherwise pin mounted using tabs for supporting the pin heads. 
While there have been described herein what are considered to be preferred 
and exemplary embodiments of the present invention, other modifications of 
the invention shall be apparent to those skilled in the art from the 
teachings herein, and it is, therefore, desired to be secured in the 
appended claims all such modifications as fall within the true spirit and 
scope of the invention. 
Accordingly, what is desired to be secured by Letters Patent of the United 
States is the invention as defined and differentiated in the following 
claims: