The invention relates to the general field of single or double flow turbine engines, and more particularly to cooling blading of ventilated distributors.
As shown in
The hot combustion gases from this combustion are then expanded in different turbine stages 6, 7. A first expansion is performed in a high-pressure stage 6 immediately downstream of the chamber and which receives the gases at the highest temperature. The gases are again expanded while being guided through the so-called low-pressure turbine stages 7.
A high-pressure 6 or low-pressure 7 turbine, conventionally includes one or more stages, each consisting of a row of fixed turbine blading, also called a distributor 8 shown in
The distributor 8 comprises a plurality of blades distributed radially with respect to an axis of rotation X of the turbine engine connecting a radially inner annular element (or inner platform) and a radially outer annular element (or outer platform). The entirety forms an annular stream facing the movable turbine blading.
More precisely, the distributor 8 is formed of fixed blading disposed in a ring which can, if required, be divided into a plurality of segments distributed circumferentially around the axis X of the turbine engine. Each segment comprises one or more fixed adjacent bladings secured to a ring sector element as well as an upstream retention means and a downstream retention means. Here, upstream and downstream are defined by the gas flow direction in the turbine engine.
The distributor 8 bladings are generally obtained by casting and are made of a nickel-based superalloy or single crystal material which has very good thermal resistance.
The distributors 8 of the high-pressure turbines are parts exposed to very high thermal stresses. They are in effect placed at the outlet of the combustion chamber and therefore have extremely hot gases passing through them, which subject them to very strong thermal loads, the temperature of the gas at the combustion chamber outlet being considerably greater than the melting temperature of the materials constituting the distributor 8. The stream temperature at the inlet of the distributor 8 can in fact locally attain 2000° C., while it is not rare to observe serious damage at certain points of the part where the melting temperature is less than 1400° C.
In order to reduce the temperature of the part and limit its degradation, cooling of the distributors 8 is therefore necessary. Customarily, the function of cooling the distributors 8 is provided by one or more inserts placed inside the distributor 8 bladings. An insert is a hollow sheet-metal or cast part comprising cylindrical bores generally formed using a laser and assuming as well as possible the shape of the blading to be cooled. “Fresh” air collected at the compressor of the turbine engine impacts, through these bores, the inner face of the blading to cool it.
The inner face of the blading is thus cooled by these jet impacts and a forced convection phenomenon between the insert and the wall of the profile. The distance between the insert and the inner face of the blading, called the air gap, is therefore constant.
However, two phenomena control the cooling of the blading, namely jet impacts and forced convection between the insert and the inner face of the blading. One of the predominant parameters in the efficiency of cooling of these two modes is the value of the air gap. In fact, the air gap should be minimal if it is desired to maximize forced convection, but it must not be too small if it is desired to maximize the impact height of the jets (which corresponds to the distance between the outlet of a bore and the inner wall of the blading) so as to optimize the efficiency of the jet impacts.
Currently, the air gap being constant, a compromise is made regarding its value so as not to degrade too strongly the jet impacts to the benefit of effective forced convection.
The performance of a turbine engine is however connected in part to the ventilation system installed. In fact, all the air collection carried out to cool the components penalize the thermodynamic cycle of the turbine engine, degrade power and the specific fuel consumption of the engine. It is therefore necessary to limit to a strict necessary minimum the air collection. The efficiency of the cooling systems used is therefore paramount for the performance of the engine and the lifetime of the component concerned.
Document EP 2 228 517 describes distributor blading of a turbine engine, a blade and an insert housed in the blade in which openings are formed. The wall of the insert is further locally folded at the openings so as to cross their air jets and create turbulence.
Document EP 1 284 338 describes, for its part, distributor blading of a turbine engine, a blade and an insert housed in the blade in which openings are formed. The wall of the insert is discontinuous so as to form overlaps and modify the direction of impact of the air jets sent by the openings onto the inner face of the blade.
One objective of the invention is therefore to optimize the cooling of the distributor blading so as to limit the quantity of fresh air used, the final objective being the limitation of thermo-mechanical damage (cracks, burns, oxidation, etc.).
For this purpose, the invention proposes turbine engine distributor blading, said blading having:
The blading insert comprises a series of recesses of overall hemispheric, egghead or water drop shape, formed in the closed wall and leading to the outer skin. Moreover, the through openings are formed in said recesses and the impact heights between said through openings and the facing pressure side wall or suction side wall are greater than the air gap.
Certain preferred but not limiting features of the blading described above are the following, taken individually or in combination:
According to a second aspect, the invention also proposes a distributor for a turbine of a turbine engine comprising an inner annular platform and an outer annular platform, coaxial around an axis as well as a series of distributor bladings as described above, said bladings being circumferentially distributed around the axis between the inner platform and the outer platform.
According to a third aspect, the invention proposes a method for manufacturing a distributor blading as described above, wherein the insert is made by selective melting on a powder bed by a high-energy beam.
Other features, aims and advantages of the present invention will be more apparent upon reading the detailed description that follows, and with reference to the appended drawings, given by way of non-limiting examples and in which:
Referring first to
Conventionally, the turbine 6 comprises one or more stages, each consisting of a distributor 8 followed by a row of movable turbine blades 3 spaced circumferentially all the way around the disk of the turbine 6.
The distributor 8 deflects the gas flow from the combustion chamber 5 toward the movable blades at an appropriate angle and speed so as to drive in rotation the blades and the disk of the turbine 6. As shown in
Every blading 10 comprises a blade 12 including a pressure side wall 16 and a suction side wall 14 interconnected by a leading edge 18 and a trailing edge 19. The leading edge 18 of a blade 12 corresponds to the anterior portion of its aerodynamic profile. It faces the gas flow and divides it into a pressure side air flow which runs along the pressure side wall 16, and a suction side air flow which runs along the suction side wall 14. The trailing edge 19, for its part, corresponds to the posterior portion of the aerodynamic profile, where the pressure side and suction side flows rejoin.
The distributor 8 further comprises a cooling system. To this end, and with reference to
A series of recesses 25, which lead to the outer skin 24, are further formed in the closed wall 12 of the insert 20. The through openings 28 are formed in the recesses 25 and the impact heights h, shown in
With reference to
By impact height h is meant the distance between the outlet (with respect to the cooling air flow) of the through opening 28 and the inner face 15 of the facing wall of the blade 12, that is the pressure side wall 16 or the suction side wall 14, along the axis X of cooling air flow into the through opening 28.
This configuration of the blading 10 allows both providing a small air gap 30 between the blade 12 and the insert 20, and thereby maintaining the efficiency of forced convection during discharge of the air after impact through the through openings 28, while still improving the efficiency of the impact thanks to the impact height h increased by the recesses 25 which offset the outlet of the through openings 28 with respect to the outer skin 24 of the insert 20.
In one embodiment, the impact height h is comprised between 1.0 mm and 3.0 mm, preferably between 1.0 and 2.0 mm, for example about 1.5 mm, when the air gap 30 is comprised between 0.5 and 1.0 mm, preferably between 0.5 and 0.8 mm, for example on the order of 0.6 mm.
The through openings 28 have a periphery having a defined maximum width L shown in
In order to further optimize the efficiency of jet impact on the inner face 15 of the blade 12, the ratio between the impact height h and the maximum width L of all or a part of the openings is comprised between 2.5 and 10, preferably between 2.5 and 5, typically between 2.5 and 5, for example between 2.8 and 3.2. Typically, in the case of a blade 12 the closed wall 12 of which has a thickness comprised between 0.4 and 0.6 mm with an air gap 30 substantially equal to 0.6 mm, the optimal ratio between the impact height h and the maximum width L of the openings is on the order of 3. Such a ratio makes it possible in particular to obtain an impact distance of 1.5 mm.
As best seen in
Such a shape further allows such ratios of impact height h over maximum with L to be expected.
Thus, in the exemplary embodiment illustrated in
In a variant embodiment, the inner face 15 of the pressure side wall 14 and the suction side wall 16 of the blade 12 can comprise studs 13 protruding from said inner face 15 in the direction of the insert 20, so as to protect the jet impacting the inner face 15 of the blade 12 against shearing flow. The studs 13 can for example have a triangular or V cross-section overall, a tip of the cross-section extending in the direction of the leading edge 18 of the blade 12.
This variant embodiment, coupled with the optimum maximum L width L and impact height h, makes it possible to obtain effective and constant cooling and over the entire profile of the blade 12.
The configuration of the insert 20 and, if necessary, the provision of studs 13 on the inner face 15 of the blade 12, brings about a significant gain in the local impact efficiency of the distributor 8 cooling and the possibility of managing the efficiency of forced convection in the air gap 30 which still limiting the shear of the downstream rows of impacts by those located further upstream. The optimization of all these parameters further allows the best use of the air used for cooling the wall. At iso-flow rate, this allows it to be more effective thermally (lifetime gain) or to reduce the flow rate to iso-thermal efficiency, which translates into a gain in performance of the engine.
The blade 12 can be obtained conventionally, for example by casting in a suitable material such as a nickel-based superalloy or single crystal material which has good thermal resistance. As a variant, the blade 12 can be obtained by selective melting on a powder bed by a high-energy beam.
The insert for its part can for example be obtained by casting or by selective melting on a powder bed by a high-energy beam. Selective melting on a powder bed by a high-energy beam allows in particular obtaining an insert for a lower cost (in comparison with casting), creating recesses 25 (and if necessary bulges 27) of suitable form. The outer wall of the insert can then have a thickness comprised between 0.4 and 0.8 mm, for example about 0.6 mm, or even 0.4 mm.
Number | Date | Country | Kind |
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15 56860 | Jul 2015 | FR | national |
Filing Document | Filing Date | Country | Kind |
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PCT/FR2016/051866 | 7/20/2016 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2017/013354 | 1/26/2017 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
3844343 | Burggraf | Oct 1974 | A |
6318963 | Emery | Nov 2001 | B1 |
20100232946 | Propheter-Hinckley | Sep 2010 | A1 |
20100247327 | Malecki | Sep 2010 | A1 |
20140105726 | Lee | Apr 2014 | A1 |
20140290257 | Okita | Oct 2014 | A1 |
20160023275 | Propheter-Hinckley | Jan 2016 | A1 |
20160108755 | Carr | Apr 2016 | A1 |
20160265774 | Cunha | Sep 2016 | A1 |
Number | Date | Country |
---|---|---|
0919698 | Jun 1999 | EP |
1284338 | Feb 2003 | EP |
2228517 | Sep 2010 | EP |
2792850 | Oct 2014 | EP |
2998496 | May 2014 | FR |
Entry |
---|
Preliminary Research Report and Written Opinion received for French Application No. 1556860, dated Jun. 14, 2016, 7 pages (1 page of French Translation Cover Sheet and 6 page of original document). |
International Search Report and Written Opinion received for PCT Patent Application No. PCT/FR2016/051866, dated Oct. 31, 2016, 17 pages (8 pages of English Translation and 9 pages of Original Document). |
International Preliminary Report on Patentability received for PCT Patent Application No. PCT/FR2016/051866, dated Feb. 1, 2018, 13 pages (7 pages of English Translation and 6 pages of Original Document). |
Number | Date | Country | |
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20180216476 A1 | Aug 2018 | US |