The present invention relates to the field of the turbine engines and in particular to a turbine engine vane equipped with a cooling circuit intended to cool it.
The prior art comprises the documents EP-A2-1 793 083, EP-A1-1 267 039 and US-A1-2013/259645.
The turbine engine vanes, in particular the high-pressure turbine vanes, are subjected to very high temperatures that can shorten their service life and degrade the performance of the turbine engine. Indeed, the turbine engine turbines are arranged downstream of the combustion chamber of the turbine engine, which ejects a hot gas flow that is expanded by the turbines and allows them to be driven in rotation for the operation of the turbine engine. The high-pressure turbine, which is located directly at the outlet of the combustion chamber, is subject to the highest temperatures.
In order to allow the turbine vanes to withstand these severe thermal stresses, it is known to provide a cooling circuit in which relatively cooler air circulates, which is taken at the level of the compressors, the latter being located upstream of the combustion chamber. More specifically, each turbine vane comprises a blade with a pressure side surface and a suction side surface which are connected upstream by a leading edge and downstream by a trailing edge. The cooling circuit comprises a cavity located inside the vane and opening into orifices which are located in the vicinity of the trailing edge. These orifices deliver cooling air jets to the walls of the blade.
However, the orifices are not supplied with air evenly. A calibration device has been developed to ensure that the majority of the cooling air flow is delivered only to the first orifice which is radially closest to the root of the vane. This calibration device comprises a partition which is provided with holes and which is placed in the cooling air path upstream of the orifices. These holes allow each orifice to produce a localized jet that will cool the pressure side surface.
However, the holes of this calibration device are extremely loaded mechanically due to local thermal gradients, the centrifugal force linked to the rotation of the vane which introduces tensile stresses, and the geometry of the holes which induces a stress concentration factor “Kt”.
The objective of the present invention is to reduce the mechanical stresses that suffer in particular the holes of the device for calibrating the cooling air while avoiding significant structural modifications to the device itself and to the vane.
This is achieved in accordance with the invention by a turbine engine vane comprising:
Thus, this solution allows to achieve the above-mentioned objective. In particular, the particular shape of the calibration conduits allows a strong reduction of the mechanical stresses, and in particular of the static stresses and to increase the radius of the section of the conduit while remaining at iso section, thus at iso flow rate. The load is distributed between the elongated ends of the hole, which increases the contact area of the hole and further reduces the stress. Such a shape allows also to limit the risk of recrystallization of the grains of the material of which the calibration device and the vane are made. Finally, this configuration allows a gain in mass compared to the conventional solutions consisting of increasing the thickness (and therefore the mass) of the partition of the calibration device.
The vane also comprises one or more of the following characteristics, taken alone or in combination:
The invention also relates to a turbine engine turbine comprising at least one turbine engine vane having the above characteristics.
The invention further relates to a turbine engine comprising at least one turbine engine turbine as aforesaid.
The invention will be better understood, and other purposes, details, characteristics and advantages thereof will become clearer upon reading the following detailed explanatory description of embodiments of the invention given as purely illustrative and non-limiting examples, with reference to the appended schematic drawings in which:
This turbine engine 1 with double-flow generally comprises a fan 2 mounted upstream of a gas generator 3. In the present invention, and in general, the terms “upstream” and “downstream” are defined with respect to the flow of gases in the turbine engine and here along the longitudinal axis X (and even from left to right in
The gas generator 3 comprises, from upstream to downstream, a low-pressure compressor 4a, a high-pressure compressor 4b, a combustion chamber 5, a high-pressure turbine 6a and a low-pressure turbine 6b.
The fan 2, which is surrounded by a fan casing 7 carried by a nacelle 8, divides the air entering the turbine engine into a primary air flow which passes through the gas generator 3 and in particular in a primary duct 9, and into a secondary air flow which circulates around the gas generator in a secondary duct 10.
The secondary air flow is ejected by a secondary nozzle 11 terminating the nacelle while the primary air flow is ejected outside the turbine engine via an ejection nozzle 12 located downstream of the gas generator 3.
The high-pressure turbine 6a, like the low-pressure turbine 6b, comprises one or more stages. Each stage comprises a stator blade ring mounted upstream of a mobile blade ring. The stator blade ring comprises a plurality of stator or fixed vanes, referred to as distributor, which are distributed circumferentially about the longitudinal axis X. The moving blade ring comprises a plurality of moving vanes which are equally circumferentially distributed around a disc centered on the longitudinal axis X. The distributors deflect and accelerate the aerodynamic flow leaving the combustion chamber towards the mobile vanes so that the latter are driven in rotation.
With reference to
The vane 20 comprises a cooling circuit 28 intended to cool the walls of the blade subjected to the high temperatures of the primary air flow passing through the combustion chamber 5 and leaving the combustion chamber. The cooling circuit 28 comprises an internal cavity 29 which extends radially inside the blade, and in particular between the pressure side wall 24 and the suction side wall 25. The root 23 comprises a supply channel 30 which comprises a cooling fluid inlet 31 (here cooling air) taken from upstream of the combustion chamber such as from the low-pressure compressor and which opens into the cavity 29. The channel 30 also opens onto a radially internal face 41 of the root of the vane. The cooling circuit also comprises outlet orifices 32 that are arranged in the vicinity of the trailing edge 27 of the blade. The outlet orifices are oriented along the longitudinal axis X. Furthermore, the outlet orifices 32 are aligned and evenly distributed substantially along the radial axis.
In
As can also be seen in
More specifically, the calibration device 33 comprises a partition 35 which extends along the radial axis (in the installation situation) and is defined in a median plane containing the radial axis. This partition 35 is pierced by calibration conduits 34 on either side along an axis substantially perpendicular to the median plane of the partition. The wall of the partition is about 1.5 mm thick. The conduits 34 are aligned and evenly distributed along the radial axis along the partition. Similarly, in the installation situation, the conduits 34 are substantially opposite the outlet orifices 32 of the blade. In other words, the cooling air flows substantially axially through the calibration conduits.
In the present example of embodiment and as can be seen in detail in
Advantageously, but in a non-limiting way, the vane is made of a metal alloy and according to a manufacturing method using the lost wax casting technique. The metal alloy is preferably nickel-based and can be monocrystalline.
With reference to
The ratio between the height and the width H/L is between 0.5 and 3, and preferably between 1.4 and 2. In particular, the height H is between 1.4 times the width L and 2 times the width L. In this way, the conduits are spaced sufficiently far apart radially to reduce the static stress. The lower limit of the H/L ratio is the limit at which the gain on static stress becomes interesting.
Each conduit 34 also has two rectilinear portions referred to as “first portion” 36 and “second portion” 37 which are opposite with respect to width L passing through the central axis A. The first and the second portions 36, 37 are parallel to each other and extend along the radial axis. This configuration allows to reduce locally the stress concentration factor “kt” and thus the stress. This is because the tensile forces are exerted in a direction parallel to the radial axis. The two portions 36, 37 each extend over a distance d between a first top 36a, 37a and a second top 36b, 37b. This distance d is about 0.2 mm.
Likewise, each conduit comprises two rounded ends called “first end” 38 and “second end” 39 which are opposite to the height H passing through the central axis A.
Advantageously, but in a non-limiting way, each conduit 34 comprises a double radius so as to increase the value of the nominal radius R0 of a conventional conduit TA of circular section of the prior art (shown in dotted lines in
We can see that there are four circular arc portions 40 of the first radius R1. The portions 40 are symmetrical with respect to a first median plane P1 passing through the central axis and perpendicular to the width L. These portions 40 are also symmetrical with respect to a second median plane P2 passing through the central axis and perpendicular to the height H.
In the example of
In this example, the value of the first radius R1 is twice the nominal radius R0 of the circular conduit. The conduit with a circular transverse section has a passage area equal to that of the transverse section of the conduit with an oblong transverse section. The value of the nominal radius R0 is about 0.35 mm.
The first and second ends 38, 39 are rounded along a circular arc with each a radius R2, called “second radius R2”. In this example, the value of the second radius R2 is smaller than that of the first radius R1. In particular, the value of the second radius is equal to 0.4×R1.
For a given value of the first radius R1, the value of the distance d and the value of the second radius R2 allow to minimize the section of the conduit while ensuring a consistent first radius R1 where the stresses are important.
Number | Date | Country | Kind |
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1903017 | Mar 2019 | FR | national |
Filing Document | Filing Date | Country | Kind |
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PCT/FR2020/050566 | 3/16/2020 | WO | 00 |