U.S. patent application number 15/704279 was filed with the patent office on 2018-03-22 for combustion chamber wall of a gas turbine with a fixture of a combustion chamber shingle.
The applicant listed for this patent is Rolls-Royce Deutschland Ltd & Co KG. Invention is credited to Kay HEINZE, Stefan PENZ.
Application Number | 20180080655 15/704279 |
Document ID | / |
Family ID | 59858990 |
Filed Date | 2018-03-22 |
United States Patent
Application |
20180080655 |
Kind Code |
A1 |
HEINZE; Kay ; et
al. |
March 22, 2018 |
COMBUSTION CHAMBER WALL OF A GAS TURBINE WITH A FIXTURE OF A
COMBUSTION CHAMBER SHINGLE
Abstract
The invention relates to a combustion chamber shingle of a gas
turbine combustion chamber with at least one securing bolt that is
configured in one piece with the combustion chamber shingle,
characterized in that the securing bolt is provided in one piece
with a bolt disc that is arranged at a distance from the combustion
chamber shingle, and that a free end area of the securing bolt is
provided with a thread, as well as a combustion chamber wall for
attaching the combustion chamber shingle by means of a nut.
Inventors: |
HEINZE; Kay; (Ludwigsfelde,
DE) ; PENZ; Stefan; (Werneuchen, DE) |
|
Applicant: |
Name |
City |
State |
Country |
Type |
Rolls-Royce Deutschland Ltd & Co KG |
Blankenfelde-Mahlow |
|
DE |
|
|
Family ID: |
59858990 |
Appl. No.: |
15/704279 |
Filed: |
September 14, 2017 |
Current U.S.
Class: |
1/1 |
Current CPC
Class: |
F23R 3/002 20130101;
F23R 3/60 20130101 |
International
Class: |
F23R 3/60 20060101
F23R003/60; F23R 3/00 20060101 F23R003/00 |
Foreign Application Data
Date |
Code |
Application Number |
Sep 19, 2016 |
DE |
10 2016 217 876.8 |
Claims
1. Combustion chamber shingle of a gas turbine combustion chamber
with at least one securing bolt, which is configured in one piece
with the combustion chamber shingle, wherein the securing bolt is
provided in one piece with a bolt disc that is arranged at a
distance from the combustion chamber shingle and wherein a free end
area of the securing bolt is provided with a thread.
2. Combustion chamber shingle according to claim 1, wherein the
free end area of the securing bolt that is provided with a thread
has a larger diameter than the area of the securing bolt between
the combustion chamber shingle and the bolt disc.
3. Combustion chamber shingle according to claim 1, wherein the
bolt disc has a conical shape in cross-section.
4. Combustion chamber shingle according to claim 1, wherein the
bolt disc is configured in a dish-shaped manner as a biasing
spring.
5. Combustion chamber shingle according to claim 1, wherein the
bolt disc has a larger thickness radially inside than at the
radially outer area.
6. Combustion chamber wall of a gas turbine combustion chamber with
a combustion chamber wall and at least one combustion chamber
shingle that is mounted at the inner side of the combustion chamber
wall according to claim 1, wherein the bolt disc abuts the
combustion chamber wall, and the securing bolt is screwed in at the
combustion chamber wall by means of a nut.
7. Combustion chamber wall according to claim 6, wherein a washer
is arranged between the nut and the combustion chamber wall.
8. Combustion chamber wall according to claim 6, wherein the bolt
disc and/or the washers is provided with at least one cooling air
recess.
9. Combustion chamber wall according to claim 6, wherein the washer
is provided with a ring flange, which surrounds the securing bolt
and extends through a recess of the combustion chamber wall,
through which the securing bolt is guided.
10. Combustion chamber wall according to claim 6, wherein the
external diameter of the bolt disc is substantially equal to the
external diameter of the washers.
11. Combustion chamber wall according to claim 6, wherein the load
path for attaching the combustion chamber shingle at the combustion
chamber wall extends through the securing bolt, the bolt disc, the
combustion chamber wall, the washers, and the nut.
Description
[0001] This application claims priority to German Patent
Application DE102016217876.8 filed Sep. 19, 2016, the entirety of
which is incorporated by reference herein.
DESCRIPTION
[0002] The invention relates to a combustion chamber shingle of a
gas turbine combustion chamber as well as to a combustion chamber
wall of a gas turbine combustion chamber, including the use of the
combustion chamber shingle according to the invention.
[0003] Typical combustion chambers of gas turbines consist of an
inner and an outer combustion chamber wall. Shingles are laterally
attached at these combustion chamber walls, facing towards the
interior space of the combustion chamber. These shingles protect
the combustion chamber walls from the high temperatures that occur
during the combustion process.
[0004] Arising here is the general problem of attaching the
shingles at the combustion chamber wall in a suitable manner in
such a way that they are secured in the long run during operation.
For this purpose, the shingles are usually screwed to the
combustion chamber by means of a wall fixation element. Such
fixation elements may for example be configured in the form of stud
bolts that are connected to the shingle.
[0005] In order to cool the shingles, the combustion chamber walls
have impingement cooling holes through which cooling air is
introduced into the intermediate space between the combustion
chamber wall and the shingle. This air is discharged from the hot
side of the shingle facing towards the interior space of the
combustion chamber through the effusion cooling holes that are
provided in the shingle. The cooling air that is [discharged] from
the effusion cooling holes settles on the hot side of the shingle
as a cooling air film, and causes it to be cooled.
[0006] It is known from the state of the art to provide the
shingles with a shingle bolt, in one piece with the shingle. During
the attachment of the shingles, the shingle bolt is guided through
suitable recesses of the combustion chamber wall and screwed on
from the outside. Strength tests have shown that material creeping
occurs at the transition from the shingle to the shingle bolt or
the securing bolt at the given temperatures. As a result, the
service life of the shingle is considerably reduced as it may
detach from the combustion chamber wall. Further, it has proven to
be disadvantageous that cooling can be realized only to a limited
extent in an area where the bolt is connected in one piece to the
shingle, because large material accumulations are present in that
location. Thus, this transitional area between the bolt and the
shingle leads to thermal problems.
[0007] The following printed documents are referred to as the
underlying state of the art:
[0008] What is known from EP 1 413 831 A1 is a construction in
which the shingles are retained by hook-shaped elements. This
construction requires an elaborate manufacturing and complex
mounting process. A similar hook construction is also shown in EP 2
886 962 A1.
[0009] In EP 2 873 921 A1, a separate securing bolt is used that is
inserted into a suspension device of the shingle. This construction
also entails a considerable manufacturing and mounting effort.
[0010] In the construction that is known from EP 2 295 865 A2, it
is provided that an attachment area is formed at a shingle, with a
screw being screwed into it. Also in this construction, large
material accumulations are present in the area of the attachment,
which may lead to cooling problems.
[0011] EP 2 743 585 A1 shows a bolt which is connected in one piece
to the shingle and in which the above-mentioned disadvantages may
occur. A similar solution is also shown in EP 2 700 877 A2, wherein
additional measures are provided for cooling the transition between
the shingle and the bolt.
[0012] EP 2 738 470 A1 describes a solution in which the mixing air
holes inside the combustion chamber shingle and the combustion
chamber wall are used for screwing the shingle to the combustion
chamber wall by means of an additional attachment element.
Additional cooling air channels are formed for the purpose of
cooling.
[0013] Thus, in the state of the art there is the general problem
that the attachment of the bolt at the combustion chamber shingle
can considerably reduce the service life of the total construction
as a result of thermal loads.
[0014] The invention is based on the objective to create a
combustion chamber shingle as well as a combustion chamber wall in
which the disadvantages of the state of the art are avoided, and
which facilitate a thermally optimized solution with a long service
while at the same time having a simple structure and a simple,
cost-effective manufacturability.
[0015] According to the invention, this objective is achieved by
combinations of the features of the independent claims, with the
respective subclaims showing further advantageous embodiments of
the invention.
[0016] As for the combustion chamber shingle, it is provided
according to the invention that it is configured in one piece with
the securing bolt. However, the securing bolt additionally has a
bolt disc that is connected in one piece to the securing bolt,
namely in such a manner that the bolt disc has a distance to the
combustion chamber shingle. The free end area of the securing bolt
that extends from the bolt disc is provided with a thread.
[0017] The combustion chamber shingle according to the invention is
characterized by a series of significant advantages. Thanks to the
bolt disc it is achieved that the combustion chamber shingle does
not directly abut the combustion chamber wall. Instead, the bolt
disc forms a counter bearing which is supported against the
combustion chamber wall and is braced by means of a nut that is
screwed to the thread of the securing bolt. In this way, an
intermediate space through which the cooling air can flow is
created between the bolt disc and the combustion chamber shingle.
This leads to an improvement of the cooling by means of the cooling
air that is introduced into the intermediate space between the
combustion chamber shingle and the combustion chamber wall.
[0018] It is particularly advantageous if the end area of the
securing bolt that is provided with the thread has a larger
diameter than the area of the securing bolt between the combustion
chamber shingle and the bolt disc. This means that the securing
bolt can have a considerably smaller diameter between the
combustion chamber shingle and the bolt disc, so that less material
accumulation is present in that area, which in turn leads to a
reduction of the mass to be cooled. This results in a smaller
thermal impingement, which in total leads to a longer service life
of the combustion chamber shingle, because the material creeping
processes as they are known from the state of the art either do not
occur at all or occur only to a very limited extent.
[0019] According to the invention, the cross-section of the bolt
disc can have a conical shape, so that the force transmission into
the combustion chamber shingle is improved.
[0020] In an alternative or additional embodiment, the bolt disc
can be configured in a dish-shaped manner so as to have a certain
elasticity. Here, the attachment disc serves as a biasing spring
for additionally securing the screw connection by means of the
nut.
[0021] In order to minimize the heat transfer into the shingle and
to maximize the cooled surface on the hot side it can be
advantageous to provide the bolt with a smaller diameter at the
transition to the shingle than at the thread area of the bolt, as
has been described. In addition, it is possible to select the
thickness of the bolt disc in such a manner that the bolt disc has
a smaller thickness at the radially outer area than at the radially
inner area.
[0022] All this leads to improved cooling options of the shingle in
the attachment area.
[0023] As for the structure of the combustion chamber wall of a gas
turbine combustion chamber, it is provided according to the
invention that the nut for attaching the securing bolt abuts the
combustion chamber wall. The result is a load path that extends
through the free area of the securing bolt, through the nut,
through the edge area of the associated recess of the combustion
chamber wall, and through the bolt disc. Thus, the attachment area
of the securing bolt at the combustion chamber shingle is not
subjected to loads due to the screw connection. What results in
this manner is a considerable reduction of the mechanical load in
this area. This leads to reduced material creeping, and thus to a
reduced susceptibility to failure.
[0024] In addition, it can be advantageous to arrange a separate
washer between the nut and the combustion chamber wall. The washer
may for example serve for compensating dimensional measurements,
and for providing a sufficient contact surface of the nut.
[0025] To additionally cool the area of the screw connection of the
combustion chamber shingle, it can be advantageous if additional
cooling air recesses are provided in the bolt disc and/or in the
washer.
[0026] Further, the washer can be provided with a ring flange that
surrounds the securing bolt and extends through the recess of the
combustion chamber wall through which the securing bolt is guided.
This leads to a simplified mounting process and takes into account
the dimensional deviations of the recesses of the combustion
chamber wall.
[0027] The external diameter of the bolt disc is substantially
equal to the external diameter of the washer. However, other
dimensioning options can also be advantageous.
[0028] In the following, the invention will be described based on
an exemplary embodiment in connection with the drawing. Herein:
[0029] FIG. 1 shows a schematic rendering of a gas turbine engine
according to the present invention,
[0030] FIG. 2 shows a simplified, partially perspective sectional
view of a combustion chamber shingle with the shingle bolt
according to an exemplary embodiment of the invention, and
[0031] FIG. 3 shows a rendering analogous to FIG. 2, including a
rendering of the resulting load path.
[0032] The gas turbine engine 10 according to FIG. 1 represents a
general example of a turbomachine in which the invention may be
used. The engine 10 is configured in a conventional manner and
comprises, arranged successively in flow direction, an air inlet
11, a fan 12 that rotates inside a housing, a medium-pressure
compressor 13, a high-pressure compressor 14, a combustion chamber
15, a high-pressure turbine 16, a medium-pressure turbine 17, and a
low-pressure turbine 18 as well as an exhaust nozzle 19, which are
all arranged around a central engine axis 1.
[0033] The medium-pressure compressor 13 and the high-pressure
compressor 14 respectively comprise multiple stages, of which each
has an arrangement of fixedly arranged stationary guide vanes 20
that extends in the circumferential direction, with the stationary
guide vanes 20 being generally referred to as stator vanes and
projecting radially inward from the core engine shroud 21 through
the compressors 13, 14 into a ring-shaped flow channel. Further,
the compressors have an arrangement of compressor rotor blades 22
that project radially outward from a rotatable drum or disc 26, and
are coupled to hubs 27 of the high-pressure turbine 16 or the
medium-pressure turbine 17.
[0034] The turbine sections 16, 17, 18 have similar stages,
comprising an arrangement of stationary guide vanes 23 projecting
radially inward from the housing 21 through the turbines 16, 17, 18
into the ring-shaped flow channel, and a subsequent arrangement of
turbine blades/vanes 24 projecting outwards from the rotatable hub
27. During operation, the compressor drum or compressor disc 26 and
the blades 22 arranged thereon as well as the turbine rotor hub 27
and the turbine rotor blades/vanes 24 arranged thereon rotate
around the engine axis 1.
[0035] FIG. 2 shows, in a partially perspective sectional view, a
combustion chamber shingle 29 provided with a securing bolt 25 that
is formed in one piece with the same. It is to be understood that
multiple such securing bolts can be provided in the area of a
shingle.
[0036] At its free end area, the securing bolt 25 is provided with
a thread 31 onto which a nut 33 can be screwed.
[0037] At a distance and in parallel to the surface of the
combustion chamber shingle, the bolt has a bolt disc 30 configured
in one piece with the same. In the shown exemplary embodiment, the
bolt disc 30 is configured as a circular disc, but it can also have
any other shape, for example it can be polygonal or
rectangular.
[0038] As shown in FIG. 2, a transitional area 36 of the securing
bolt 25 extending between the bolt disc 30 and the combustion
chamber shingle 29 is configured with a smaller diameter than the
free end area of the bolt that is provided with the thread 31. The
result is less material accumulation, which facilitates improved
cooling.
[0039] Reference sign 32 indicates a combustion chamber wall that
is provided with a recess. The securing bolt 25 is guided through
this recess. In addition, a washer 34 is inserted, with the nut 33
being supported against it. The washer 34 has a ring flange 35 that
extends into the free hole space of the combustion chamber wall 32,
and can for example serve for centering the combustion chamber
shingle 29, or for securing its position.
[0040] FIG. 3 shows the resulting load path in a rendering that is
analogous to FIG. 2. The load for the attachment of the combustion
chamber shingle 29 at the combustion chamber wall 32 thus extends
through the free area of the securing bolt 25 that is provided with
a thread 31, through the nut 33, through the washer 34, through the
combustion chamber wall 32, and through the bolt disc 30. As can be
seen here, the transitional area 36 is not submitted to any
mechanical load as a result of the screw connection, so that the
danger of material creeping can mostly be avoided.
[0041] Thus, the present invention refers to a concept for
attaching combustion chamber shingles at a combustion chamber wall.
As mentioned, the combustion chamber shingles protect the
combustion chamber housing from the high temperatures that occur
inside the combustion chamber during the combustion of kerosene. In
order to obtain a sufficiently long service life of the shingles, a
protective ceramic layer is usually applied to the hot side of the
combustion chamber shingle. Further, cooling air holes (effusion
holes) are drilled through the shingle in order to create a cooling
film of cold air on the hot side of the shingle. Here, the
invention in particular relates to the screw connection of the
combustion chamber shingles and to the optimization of the load
path. Among other things, this results in the following
advantages:
[0042] Because the load path to the screw connection is realized
via the securing bolt, the bolt disc, the combustion chamber wall,
the nut, and again through the securing bolt, this load path is
shortened considerably as compared to previously known
constructions.
[0043] Through the optimized load path, the highly stressed
structural components that serve for attaching the combustion
chamber shingle, are decoupled from the shingle surface. This
results in considerably lower temperatures in the highly stressed
structural components, which leads to a longer service life and
provides a significant protection from failure.
[0044] As mentioned, the attachment of the combustion chamber
shingle at the securing bolt is realized with a smaller diameter
than the securing bolt itself, since now only the loads that occur
during operation have to be transferred as a result of the thermal
expansion. The load path to the screw connection of the combustion
chamber shingle is thus decoupled from this transitional area of
the securing bolt to the combustion chamber shingle.
[0045] Through the construction according to the invention, it is
facilitated that additional cooling air slits (not shown) are
formed in the bolt disc or the washer, in order to provide a
further cooling and to lower the overall temperature.
PARTS LIST
[0046] 1 engine axis [0047] 10 gas turbine engine/core engine
[0048] 11 air inlet [0049] 12 fan [0050] 13 medium-pressure
compressor (compactor) [0051] 14 high-pressure compressor [0052] 15
combustion chamber [0053] 16 high-pressure turbine [0054] 17
medium-pressure turbine [0055] 18 low-pressure turbine [0056] 19
exhaust nozzle [0057] 20 guide vanes [0058] 21 core engine housing
[0059] 22 compressor rotor blades [0060] 23 guide vanes [0061] 24
turbine rotor blades [0062] 25 securing bolt [0063] 26 compressor
drum or compressor disc [0064] 27 turbine rotor hub [0065] 28
outlet cone [0066] 29 combustion chamber shingle [0067] 30 bolt
disc [0068] 31 thread [0069] 32 combustion chamber wall [0070] 33
nut [0071] 34 washer [0072] 35 ring flange [0073] 36 transitional
area
* * * * *