FR2463849A1 - Blade for gas turbine rotor - has outer ceramic liner fitted over metal core and held by enlarged head and pin into rotor root fixing - Google Patents

Abstract

The rotor blade comprises a core made from a heat resistant metal. This core has a central shaped web (7), with cooling slots (11), and its head (9) is enlarged at the tip to form a stop for a ceramic liner. This liner (4) is made from silicon nitride and fits over the metal core, up to the underside of its head. The core web is fitted into a root mounting (1a) and the core liner assembly is held by a transversal pin (8), to prevent any relative movement. The root mounting is locked into the rotor (2).

Description

 The invention relates to rotating blades of gas turbines, in particular gas turbines for engines of air vehicles.

 The invention also relates to gas turbines equipped with these improved blades.

 It is known that the thermodynamic efficiency of a gas turbine depends, among other parameters, on the temperature of the gases entering the turbine. The higher this temperature, the better the yield.

 In order for the turbine blades to withstand this high temperature, refractory metals or metal alloys have been used, protective layers limiting corrosion by gases at high temperature, various cooling devices.

Blades have also been used, not made of refractory metals or alloys, but of refractory ceramics, that is to say metallic materials, most often based on silicon.

 Such ceramics, for example those constituted by silicon nitrides, such as Si3N4, retain good mechanical characteristics up to about 1.5000C more, they have densities significantly lower than those of refractory metals or metallic alloys (about three times lower).

 However, and whatever the temperature to which a refractory ceramic is subjected, there is a poor tensile strength, which makes it difficult to produce a turbine whose hot blades are constituted by ceramic blades. Indeed, the power of a turbine is a function, in particular of its speed of rotation, and the rotating blades are subjected to considerable tensile stresses generated by centrifugal forces.

 The object of the present invention is precisely to remedy this drawback and to allow, thanks to the improvements made to the blades, the production of gas turbines whose hot rotating blades are constituted by ceramic blades.

 The blade according to the invention is made, at least in part, of ceramic, and it is characterized in that it comprises holding means arranged so that the blade is subjected to a compressive stress, at least during the operation of the turbine.

According to a first embodiment of the invention, the blade comprises a ceramic part and a metal part, and means for fixing this metal part on an inner rotor surrounded by the blades.

According to another embodiment of the invention, the blade essentially comprises a single ceramic part, and means for fixing this ceramic part to an external rotor surrounding the blades.

 The gas turbine according to the invention comprises at least one rotating vane comprising vanes made, at least in part, of ceramic, and it is characterized in that holding means are provided so that each vane is subjected to a compression stress, at least during operation of the turbine.

 According to a first embodiment of the invention relating to a turbine in which the blades are carried by an inner rotor, said blades surrounding said rotor, the holding means are constituted by mechanical means resistant to traction and interposed between the foot of dawn and its end.

According to another embodiment of the invention relating to a turbine in which the blades are carried by an external rotor, said blades being surrounded by said rotor, the holding means consist of a particular mounting of the blades on the above-mentioned external rotor .

Thanks to the arrangements just mentioned, it is possible to produce high performance turbines (gas inlet temperature into the turbine and high speed of rotation) which find application in the motorization of air vehicles, application in which the low density of ceramics is particularly appreciated.

The invention also relates to certain other arrangements which are preferably used in combination with those which have just been mentioned and which will be more explicitly discussed below.

The invention may, in any case, be well understood with the aid of the additional description which follows, as well as of the appended drawings, which supplement and drawings relate to preferred embodiments of the invention and do not include , of course, no limiting character.

Fig. 1 of these drawings is a cross-sectional view of a blade established in accordance with a first embodiment of the invention.

 Fig. 2 is a section on II-II fig. 1.

Fig. 3 is a view, in cross section, of a blade established according to a variant of the embodiment illustrated in FIG. 1.

 Fig. 4 is an axial section of a blade established in accordance with another embodiment of the invention.

Fig. 5 is a cross section along V-V fig. 4.

 In fig. 1 to 3, a rotating gas turbine blade has been shown in which the blades 1 are carried by a rotor 2 which is of the inner rotor type, that is to say that the blades 1 extend radially towards the exterior from the exterior surface 2a of said rotor 2, in such an arrangement, the vanes 1 surround the rotor 2.

 On the. fig. 4 and 5, a rotary vane of a gas turbine has been shown in which the blades 1 are carried by a rotor 2 which is of the external rotor type, that is to say that the blades 1 extend radially towards the interior from the interior bore 2b of said rotor 2; in such an arrangement, the blades 1 are surrounded by the rotor 2.

That said, and whatever the type of assembly adopted, each blade 1 is made, at least in part, of ceramic, for example silicon nitride Si3N4.

The blade 1 comprises holding means arranged so that the blade is subjected to a compressive stress, at least during the operation of the turbine.

 According to the embodiment illustrated in FIGS. 1 to 3, these holding means are constituted by mechanical means, resistant to traction and interposed between the root of the blade 1 and its end 1b.

ab
The blade 1 comprises a ceramic part 4 and a metal part 5; fixing means 6 are provided for fixing this metal part 5 to the inner rotor 2.

These mechanical means comprise, as shown in FIG. 1, for each blade 1, a central core 7 whose inner end 7 is made integral, by a device
a tif of fixing 8, of the blade root la, and the other end of which 7b comprises a transverse element 9, the part of the ceramic blade 4 being fitted onto this central core 7 before the above-mentioned device is put in place fixing 8.

This fixing device 8 can be constituted by a pin threaded in coaxial bores.

These mechanical means can also include, as shown in FIG. 3, for each blade 1, a central core 7 whose inner end 7 includes the blade root
at the, and the other end of which 7b is made integral, by a fixing device 10, with a transverse element 9, - the part of the ceramic vane 4 being fitted onto this central core 7 before being put in place of the above fixing device 10.

 This fixing device 10 can be constituted by a spindle threaded in coaxial bores.

The part of the ceramic blade 4 is therefore interposed between the blade root 1 and the transverse element 9 located
a at the end lb of the dawn. As soon as the turbine rotates, the part of the ceramic vane bears on this transverse element 9 and the vane 1, with regard to its ceramic part 4, works in compression.

As shown in fig. 1 to 3, it is advantageous to provide at least one, and preferably several cooling passages 11 between, on the one hand, the part of the ceramic vane 4, and, on the other hand, its metal part 5 Circulation means are then provided for circulating a cooling fluid in these cooling passages 11.

 These cooling passages 11 can be formed, in the form of grooves, on the surface of the central core 7 and of the transverse element 9.

These cooling passages 11 are distributed over the surface of the central core 7 (FIG. 2) and extend over the surface of the transverse element 9 after a change of direction of approximately 900.

 These cooling passages 11 are supplied with cooling fluid (air taken from the compressor cooperating with the turbine) through one or more channels 12 formed in the foot 1 of the blade 1.

at
According to a variant of the invention (not shown), at least one cooling passage is provided in the central core 7.

 According to the embodiment illustrated in FIGS. 4 and 5, the holding means consist of a particular mounting of the blades on the outer rotor 2.

 The blade 1 essentially comprises a single ceramic part 13, fixing means 14 are provided for fixing this ceramic part 13 to the external rotor 2.

These fixing means 14 may be constituted by a ceramic heel 15 intended to be kept in abutment on the internal bore 2b of the external rotor 2. This heel 15 has an upstream edge 15 and a downstream edge 15 arranged
ab to cooperate respectively with an upstream spacer 16
a and a downstream spacer 16b which hold said heel 15 in abutment on the internal bore 2b of the external rotor 2 (fig. 4).

 As shown in fig. 4 and 5, it is advantageous to provide at least one, and preferably several cooling passages 17 between the internal bore 2b of the external rotor 2 and the heel 15. Circulation means are then provided for circulating a fluid cooling in these cooling passages 17.

Other cooling passages 18 are also provided in the spacers 16 and 16b, these passageways
ab cooling 18 being supplied by the same circulation means as those supplying the cooling passages 17.

As regards the outer rotor 2, which must withstand the centrifugal forces due, on the one hand, to its own weight, and, on the other hand, to the weight of the blades which it carries, it is advantageously arranged so that its axial dimension L increases, preferably regularly, between its minimum radius R and its maximum radius RM
m -
The outer rotor 2 can then comprise an upstream flange 19 extending up to the upstream spacer 16a, and a
a downstream flange 19b extending to the downstream spacer 16b.

These flanges 19a and 19 delimit, with the rotor ex
ab térieur 2, two cavities 20 and 20
ab
As for the cooling passages 18 of the spacers 16 ses 16a and 16b, they can be delimited by the walls opposite the flanges 19 and 19b.

ab
The means for supplying cooling fluid to these cooling passages 17 and 18 (air taken from the compressor cooperating with the turbine), can then comprise - two air inlets 21 and 21 supplying respectively
ab
the two cavities 20 and 20b - a central channel 22 connecting each cooling passage
dissement 17 on the outer surface. of the external rotor
rieur 2, - orifices 23a and 23b connecting each re passage
cooling 18, respectively upstream spacers
16a and downstream 16b, on the inner surface of the rotor ex
2.

We have just described two types of rotating blades with ceramic blades (at least in part), namely a rotating blade with internal rotor (fig. 1 to 3) and a rotating blade with external rotor (fig. 4 and 5) .

 It is advantageous to have a turbine comprise a succession of these rotating blades mounted in a counter-rotating manner.

Claims (27)

 1.- Dawn for rotating blading of a gas turbine, made up, at least in part7 of ceramic, characterized in that it comprises holding means arranged so that the blade is subjected to a compressive stress, at least during the operation of the turbine.  2. A blade according to claim 1, characterized in that it comprises a ceramic part and a metal part, and means for fixing this metal part on an inner rotor surrounded by the blades. 3. A blade according to claim 1, characterized in that it essentially comprises a single ceramic part, and means for fixing this ceramic part on an external rotor surrounding the blades.  4.- Dawn according to claim 2, characterized in that the metal part is constituted by a central core, the inner end of which is made integral, by an appropriate fixing device, with a blade root, and whose l 'outer end comprises a transverse element, and by the fact that the ceramic part is arranged to be fitted on the central core of the metal part before the establishment of the above fixing device.  5.- Dawn according to claim 2, characterized in that the metal part is constituted by a central core whose inner end comprises a blade root and whose outer end is made integral, by an appropriate fixing device , of a transverse element, and by the fact that the ceramic part is arranged to be fitted onto the central friend of the metal part before the above-mentioned fixing device is put in place. 6.- Dawn according to claim 4 or 5, characterized in that at least one cooling passage is provided between the metal part and the ceramic part.  7.- Dawn according to claim 5, characterized in that the or the cooling passages are supplied with cooling fluid by the foot of one blade.  8.- Dawn according to claim 4 or 5, characterized in that at least one cooling passage is provided in the central friend of the metal part.  9.- Dawn according to claim 3, characterized in that it comprises a ceramic heel intended to be kept in abutment on the inner bore of the outer rotor.  10.- Dawn according to claim 9, characterized in that this heel has an upstream edge and a downstream edge arranged to cooperate with an upstream spacer and a downstream spacer. 11. A blade according to claim 9 or 10, characterized in that at least one cooling passage is provided, at least in part, on the outer face of the talion.  12.- Gas turbine comprising at least one rotating vane comprising vanes made, at least in part, of ceramic, characterized in that holding means are provided so that each vane is subjected to a compressive stress, at least during the operation of the turbine.  13.- gas turbine according to claim 12 and wherein the blades are carried by an inner rotor, said blades surrounding said rotor, characterized in that the holding means are constituted by mechanical means resistant to traction and interposed between the foot of dawn and its end.  14.- Gas turbine according to claim 12 and wherein the blades are carried by an external rotor, said blades being surrounded by said rotor, characterized in that the holding means are constituted by a particular mounting of the blades on the above outer rotor.  15.- Gas turbine according to claim 13, characterized in that the mechanical means comprise, for each blade, a central core whose inner end is made integral, by a suitable fixing device, with a foot of blade, and the outer end of which comprises a transverse element, the ceramic blade being fitted onto this central core before the above-mentioned fixing device is put in place.  16.- Gas turbine according to claim 13, characterized in that the mechanical means comprise, for each blade, a central core whose inner end comprises a blade root and whose outer end is made integral, by a suitable fixing device, of a transverse element, the ceramic blade being fitted onto this central core before the above-mentioned fixing device is put in place.  17.- Gas turbine according to claim 15 or 16, characterized in that at least one cooling passage is provided between, on the one hand, the ceramic vane and, on the other hand, the central friend and its transverse element, circulation means being provided for circulating a cooling fluid in the aforesaid cooling passage. 18.- gas turbine according to claim 17, characterized in that there is provided several cooling passages distributed over the surface of the central core and extending over the surface of the transverse element after a change of direction d 'around 900. 19.- Gas turbine according to claim 17 or 18, characterized in that the cooling passage or passages are supplied with cooling fluid by the foot of the blade.  20.- Gas turbine according to claim 15 or 16, characterized in that at least one cooling passage is provided in the central core.  21. A gas turbine according to claim 14, characterized in that the ceramic vane has a heel held in abutment on the inner bore of the outer rotor.  22.- Gas turbine according to claim 21, characterized in that the heel of the ceramic vane is held by an upstream spacer and a downstream spacer.  23.- Gas turbine according to claim 22, characterized in that at least one cooling passage is provided between the inner bore of the outer rotor and the heel of the blade, circulation means being provided for circulating a cooling fluid in the above cooling passage.  24.- Gas turbine according to claim 23, characterized in that cooling passages are provided in the spacers, these cooling passages being supplied by the above-mentioned circulation means. 25. A gas turbine according to claim 14 and any one of claims 21 to 24, characterized in that the outer rotor is arranged so that its axial dimension increases between its minimum radius and its maximum radius.  26.- Gas turbine according to claims 23 and 25, characterized in that the cooling passage or passages are supplied with cooling fluid by lateral cavities formed in the external rotor, the outlet of said cooling fluid being provided by at at least one radial channel formed in said outer rotor. 27.- Gas turbine, characterized in that it comprises a succession of rotating blades established according to claim 2 and according to claim 3, these blades being counter-rotating.