The invention relates to an angular sector of a turbomachine blading, in particular an angular sector of a blading such as a rectifier equipping a compressor or such as a stator equipping a turbine of this turbomachine.
Gas turbine engines comprise, in a known manner, fixed internal blading rings, which are mounted in external casings of a primary flow duct of the engine and which are axially interposed between compressor moving blading wheels or between turbine moving blading wheels of these engines. Each fixed blading ring is dynamically sealed around a compressor or turbine rotor. For this purpose, each fixed blading ring comprises an internal block of abradable material which is designed to cooperate with lip sealing elements that are rotationally integral with the associated compressor or turbine rotor to ensure gas-tightness.
Part of the gas is nevertheless likely to enter between the stationary and moving blading of the compressor or turbine rotors, in the opposite direction to the main flow circulating in the primary flow duct.
The fixed internal blading ring constitute rectifiers when they are interposed between compressor wheels, or constitute stators when they are interposed between turbine wheels.
In order to facilitate their assembly and reduce their manufacturing cost, the fixed blading rings are often made as an assembly of angular sectors that are juxtaposed next to each other to form a whole fixed blading ring. These rings thus leave an inter-sector clearance which leaves recirculation passages for the gases, no longer around the roots of the angular sectors, but between them.
Indeed, conventionally, part of the gases that pass through the fixed blading from upstream to downstream tend to recirculate from downstream to upstream through the seal that is made between the block of abradable material and the lip sealing element according to a leakage flow rate that we try to keep as minimal as possible, because it affects the performance of the corresponding compressor or turbine. Another part of the gas that passes through these blading from upstream to downstream tends to recirculate from downstream to upstream by insinuating itself between the sectors through the clearance between the sectors, also called the inter-sector clearance.
The difficulty in ensuring a satisfactory level of sealing lies in the fact that the angular sectors of the ring move due to the mechanical and thermal deformations that occur during engine operation. Thus, the inter-sector clearance and leakage flow rate vary during engine operation. Furthermore, the clearance under during hot engine operation must never be zero because contact between the sector platforms could cause ovalization of the casing, which is outside the fixed blading, and/or matting of the surfaces in contact, which could drastically increase the stresses exerted on the fixed blading, resulting in particular in a transfer of these stresses to the outer casing of the engine, which receives the fixed blading.
A transfer of these stresses could cause an ovalization of the outer casing and significantly modify the radial clearances between this casing and the adjacent moving blading, with a very negative impact on the engine in terms of service life.
Conventional sealing between two immediately adjacent angular sectors of a fixed blading ring is ensured by lip seal systems interposed between these sectors to limit leakage between sectors. These sealing systems can be used to seal ring sectors of the fixed blading in the primary flow duct, and also, in the case of a double-flow engine, to seal ring sectors of the fixed blading in the secondary flow duct.
In this technology, lips are housed between two adjacent sectors in housings that have been machined into the sectors. The lips are used to prevent the flow of gas of passing through the inter-sector clearance.
Conventionally, an angular sector of the blading ring comprises, with respect to the axis of the ring, a radially outer platform substantially in the shape of an angular section of a cylinder, a radially inner platform in the shape of an angular section of a cylinder, at least two vanes extending between said platforms, a root attached to the inner platform, and at least one block of abradable honeycomb material extending inwardly to the root. The lips interposed between two sectors are embedded in the mass of the two adjacent roots of the two sectors and in housings facing the adjacent interior and exterior platforms of the two sectors.
However, these lips are not easy to install. In addition, they require the construction of housings in the angular sectors of the fixed blading, which are expensive to manufacture.
In addition, the lips cannot be arranged along the entire radial thickness of the root for the sealing on the inside of the inner platform. Consequently, clearances remain between the sectors through which the gases can flow.
Therefore, there is a need for an alternative sealing technology to dispense with such lips and to improve the sealing between the fixed blading sectors.
Document FR-2.552.159-A1 describes a technology in which the edges of the inner platforms are shaped into a Z-profile. This configuration improves sealing efficiency, but is limited to the platforms and is only applicable to a dispenser with an unsectorized block of abradable material.
The invention proposes to take advantage of the existing abradable material block arranged inside the inner platform to provide a seal directly between transverse end walls of two adjacent angular sectors.
For this purpose, the invention proposes an angular sector of a fixed blading ring of a turbomachine, in particular of a rectifier or stator, said sector extending at a given angle around an axis of the fixed blading ring and comprising, relative to the axis of said fixed blading ring a radially outer platform, a radially inner platform, at least two vanes extending between said platforms, and at least one abradable honeycomb material block extending on the inside of the inner platform between transverse ends of the sector.
The abradable honeycomb material block comprises, for example, a radially inner radial sealing face which is configured to cooperate with lips of a labyrinth seal carried by a rotor of the turbomachine.
In accordance with the invention, this angular sector is characterized in that the abradable material block comprises at least one transverse end wall which is shaped according to a toothed profile comprising at least one tooth with a radial direction extending along an entire radial thickness of said block.
According to other characteristics of the angular sector:
The invention also relates to an assembly of two adjacent angular sectors of the type described above, characterized in that said at least one transverse end wall shaped according to a toothed profile of said adjacent angular sectors faces each other, and in that said toothed profiles are complementary.
Finally, the invention concerns a fixed blading ring of a turbomachine comprising a plurality of angular sectors of the fixed blading ring, characterized in that it comprises a given number of sectors whose juxtaposition forms the entire fixed blading ring, in that each angular sector comprises two opposite transverse end walls which are shaped into toothed profiles each comprising at least one radially oriented tooth, and in that each angular sector is assembled with each of the angular sectors adjacent thereto in an assembly of the type described above.
The invention will be better understood and other details, characteristics and advantages of the present invention will appear more clearly when reading the following description made as an example, which is not limitative, and with reference to the appended drawings, in which:
In the following description, identical reference numbers refer to parts that are identical or have similar functions.
Axial direction means by extension any direction parallel to an axis A of a turbomachine, and radial direction means any direction perpendicular and extending radially with respect to the axial direction.
A primary air flow “P” passes through the high- and low-pressure bodies and fan 12 produces a secondary air flow “S” that circulates in the turbojet engine 10, between a casing 11 and an outer casing 13 of the turbojet engine, in a cold flow channel 15. At the outlet of the nozzle 24, the gases from the primary flow “P” are mixed with the secondary flow “S” to produce a propulsion force, the secondary flow “S” providing most of the thrust here.
The LP and HP compressors 14, 16 and the HP and LP turbines 20, 22 each comprise several compressor or turbine stages respectively. As shown for example in
The LP turbine 22 also comprises rings of fixed bladings 32a, 32b, 32c, 32d of a diffuser 32 which are interposed between the turbine moving blading wheels 22a, 22b, 22c, 22d, 22e.
Each fixed blading ring 32a, 32b, 32c, 32d of the diffuser is formed by an assembly of sectors 34a, 34b, 34c, 34d of a fixed blading ring, assembled around the axis A of the turbomachine over 360° so as to constitute a complete fixed blading ring 32a, 32b, 32c, 32d around the axis A of the turbomachine.
In the same way, as illustrated in
As illustrated in more detail in
The existence of this recirculation flow rc is particularly penalizing. The recirculation flow rc tends to reduce the performance of the compressor, or similarly in the case of a turbine, the performance of the said turbine. This is why current designs tend to minimize this recirculation flow rc by equipping the angular sector 34a with sealing means with the shroud it surrounds.
As shown in
The term “lower” refers to any position close to the axis A in the radial direction, while the term “upper” refers to any position further from the axis A in the radial direction than the lower position. Finally, by “transverse” is meant any plane or surface comprising the axis A and parallel to a sectional plane of a sector 34.
Conventionally, each sector 34a comprises, with respect to the axis A of the ring 32a, a radially outer platform 38a, a radially inner platform 40a, at least two vanes 42a which extend between said platforms 38a, 40a, a root 43a which extends radially inward from the inner platform 40a and at least one block 44a of abradable honeycomb material which therefore also extends inward to the inner platform 40a between transverse ends (not shown) of the angular sector 34a.
A radially inner radial sealing face 46a is configured to cooperate with lips 48a of a labyrinth seal 50a carried by a rotor of the turbomachine, here the shroud 30a.
This configuration significantly reduces the intensity of the recirculation flow rc circulating between the sector 34a and the shroud 30a. However, it has no influence on the recirculation flow between two adjacent sectors 34a.
Conventionally, the sealing between adjacent sectors 34a is achieved by means of lips (not shown) that are received in housings facing the adjacent sectors 34a and that are arranged between these sectors 34a to form a barrier to the recirculation flow rc between the sectors 34a. This configuration is particularly costly because it requires the creation of housings for the lips, especially in the roots 43a, and because it imposes particular assembly precautions, especially with regard to the sectors that are intended to close the entire blading during its assembly.
As illustrated in
For this purpose, as illustrated in
Thus,
As shown in particular in
The fixed blading ring 32a comprises a specific number of ring sectors 34a, the juxtaposition of which forms the entire fixed blading ring 32a and it comprises at least two of these angular sectors 34a of the blading ring comprising complementary tooth profiles 54a1, 54a2. It is to be understood that all ring sectors 34a preferably comprise toothed profiles. Thus, each angular sector 34a is assembled with each of the adjacent angular sectors 34a in an assembly of the type described above, and each block 44a comprises at both ends opposite transverse end walls 52a which are shaped according to toothed profiles 54a1, 54a2 intended to cooperate with the toothed profiles 54a1, 54a2 with radially oriented teeth of the adjacent blocks 44a.
In the preferred embodiment of the invention, the abradable material block 44a of the sector 34a extends to the inner platform 40a. This configuration has been shown in
Preferably, as shown in
Each tooth 56a1 or 56a2 of each block 44a can be made in different ways. For example, teeth 56a1 or 56a2 could be attached to block 44a, provided they protrude from the block 44a. However, each tooth 56a1 or 56a2 is preferably made directly from the abradable honeycomb material of the block 44a.
The tooth profile 54a1, 54a2 of the honeycomb material block 44a can be configured in different ways, depending on the desired seal. The higher the number of teeth 56a1 or 56a2, the better the profile 54a1, 54a2 is able to provide a labyrinth that effectively reduces the flow rate of the recirculating flow rc between adjacent angular sectors 44a. On the other hand, the higher the number of teeth 56a1 or 56a2, the more the fitting tolerances of two adjacent angular sectors 44a are reduced and the more complex these adjacent sectors 44a are to achieve. It will therefore be understood that the number of teeth 56a1 or 56a2 will be the result of a compromise between the efficiency of the reduction of the recirculating flow rc and the cost of obtaining the ring 32a formed of the angular sectors 34a, this cost including the realization of these sectors 34a and their assembly.
In this configuration, as shown in
Alternatively, as shown in
Alternatively, as shown in
Although this configuration is not limiting the invention, it will be understood that the abradable honeycomb material of the block 44a comprises tubular cells (not shown) that are radially oriented in the radial direction R. This configuration provides maximum strength to the block 44a of material.
In the preferred embodiment of the invention, the honeycomb material of the block 44a is obtained by an additive manufacturing process. This configuration allows for the formation of regular cells and a regular conformation of the tooth profiles 54a1, 54a2 without any risk of deterioration as might be caused by a material removal process.
The invention thus makes it possible to ensure the sealing between angular sectors 32a of the fixed blading ring in a simple and effective manner, and to limit the flow rate of the recirculation flow rc between these angular sectors 32a, which allows to improve the performance of a compressor or a turbine equipped with such angular sectors of the blading ring 32a in a consequent manner.
Number | Date | Country | Kind |
---|---|---|---|
1854334 | May 2018 | FR | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/FR2019/051159 | 5/22/2019 | WO |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2019/224476 | 11/28/2019 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
4295785 | Lardellier | Oct 1981 | A |
4623298 | Hallinger | Nov 1986 | A |
20020106276 | Tomita | Aug 2002 | A1 |
20110241295 | Voisine | Oct 2011 | A1 |
20140205444 | Zheng | Jul 2014 | A1 |
20160273380 | Stiehler | Sep 2016 | A1 |
20180258784 | Schlothauer | Sep 2018 | A1 |
20180355745 | Mathew | Dec 2018 | A1 |
Number | Date | Country |
---|---|---|
0017534 | Oct 1980 | EP |
1229213 | Aug 2002 | EP |
2552159 | Mar 1985 | FR |
2008180149 | Aug 2008 | JP |
Entry |
---|
English Translation of the Written Opinion of the International Searching Authority dated Sep. 17, 2019, issued in corresponding International Application No. PCT/FR2019-051159, filed on May 22, 2019, 5 pages. |
International Search Report dated Sep. 17, 2019, issued in corresponding International Application No. PCT/FR2019/051159, filed May 22, 2019, 6 pages. |
Written Opinion of the International Searching Authority dated Sep. 17, 2019, issued in corresponding International Application No. PCT/FR2019/051159, filed May 22, 2019, 6 pages. |
Number | Date | Country | |
---|---|---|---|
20210207488 A1 | Jul 2021 | US |