This application claims priority from European Patent Application No. 16164581.7 filed on Apr. 8, 2016, the disclosure of which is incorporated by reference.
The present invention relates to a blade, in particular a blade of a gas turbine engine.
Gas turbine engines have a turbine where hot gas is expanded to gather mechanical work. Typically the turbine has a plurality of stages, each comprising vanes (which do not rotate) and blades (which rotate).
The blades have to withstand very severe conditions, due for example to the high centrifugal forces and the high temperature of the gas they are immersed in. The conditions are particularly severe for long blades, such as the blades of the last stages (e.g. third, fourth or subsequent stages) of the turbine, because of the particularly high centrifugal forces.
In order to provide blades able to withstand severe conditions, blades made of ceramic matrix composite material (CMC) have been proposed. CMC is a composite material having carbon or ceramic fibers and a ceramic matrix. US 2012/0 195 766 A1 discloses a blade of this kind.
In particular, in the following reference is made to blades whose root has a shell structure; a shell structure is to be understood as a hollow structure having walls made of CMC. The airfoil can have a shell structure as well or it can have a solid structure; the airfoil is advantageously made of CMC.
A problem with these kinds of blades is the connection of the blades to the rotor. In fact, due to the high stress during operation, there is the risk that the hollow structure of the root collapses.
An aspect of the invention includes providing a blade with a reduced risk that, during operation, the root or portions thereof may collapse.
These and further aspects are attained by providing a blade in accordance with the accompanying claims.
Further characteristics and advantages will be more apparent from the description of a preferred but non-exclusive embodiment of the blade, illustrated by way of non-limiting example in the accompanying drawings, in which:
With reference to the figures, these show a blade 1 comprising an airfoil 2 and a root 3. The blade 1 can be manufactured in one piece in ceramic matrix composite material CMC (this is the preferred solution).
The airfoil 2 has a tip 4 and the root 3 has a free end 5.
The root 3 has diverging walls 7; e.g.
The diverging walls 7 are made of a ceramic matrix composite material CMC and a reinforcement element 8 is provided between the diverging walls 7.
The diverging walls 7 can be made in one layer or preferably in a plurality of layers 9. This is advantageous in particular for diverging walls 7 of large thickness; in addition a plurality of layers 9 for the diverging walls 7 improves load distribution among the layers 9. An embodiment with diverging walls 7 having a plurality of layers 9 is e.g. shown in
The diverging walls can also be provided with intermediate layers 11, made of a material different from the ceramic matrix composite material and provided between the layers 9 of ceramic matrix composite material; the intermediate layers 11 can be made of the same material as the reinforcement element 8.
The intermediate layer or layers 11 can extend only substantially in correspondence of the root 3, as shown in
The reinforcement element 8 can be made from metal or other material; use of metal over other materials such as composite materials like CMC is advantageous because manufacturing is easy and the material (metal) can be chosen according to the needs as for strengths, weight, etc.; in addition, since the reinforcement element 8 is only confined at the root or possibly only extends in the airfoil for a limited portion thereof, the centrifugal forces caused by the reinforcement element 8 are limited and within acceptable limits for the blade.
The attached figures show the reinforcement element 8 with diverging walls 13; the diverging walls 7 of the root rest on the diverging walls 13 of the reinforcement element 8.
In different embodiments the reinforcement element 8 can be defined only by the diverging walls 13 with a connecting member interposed between them, or it can be defined by a massive element having the diverging walls 13 (this embodiments is shown in the attached figures).
In this case, a tubular element 15 made of ceramic matrix composite material CMC or metal is preferably provided in the cooling passage 14, with the side surface of the tubular element 15 resting on the side surface of the cooling passage 14 or not. The tubular element can at least partially carry the load, in particular the centrifugal load.
The cooling passage can have any cross section, e.g. round, oval, square, rectangular, triangular, etc.; likewise, the tubular element can have any cross section, e.g. round, oval, square, rectangular, triangular, etc.
Reference 16 indicates the side surface of the tubular element 15 and the side surface of the cooling passage 14 resting one against the other.
The cooling passage 14 extends substantially in the direction 17 of the airfoil 2.
In this case a duct 23 for cooling air circulation can be provided between the rotor 20 and the blade 1.
A sacrificial layer 18 can be provided on the diverging walls 7; the sacrificial layer 18 can extend over the whole surface of the diverging walls or only a part thereof. The sacrificial layer 18 is arrange to be damaged in place of the diverging walls 7 and/or rotor 20 during operation; for example the sacrificial layer 18 can be made of metal being the same or also different from the metal of the reinforcement element 8. Other materials are naturally possible for the sacrificial layer 18.
In addition a bounding layer 19 can be provided between the diverging walls 7 and the reinforcement element 8, in order to promote reciprocal adhesion. For example the bounding layer can be a glue layer.
The blade 1 is preferably a long blade, such as a blade of a downstream stage of a gas turbine, e.g. third, fourth or subsequent stage. The blade can thus have a longitudinal length between the root free end 5 and the airfoil tip 4 of at least 0.8 m and preferably 1 m and more preferably 1.15 m. In a preferred embodiment the blade 1 has a longitudinal length between 1.15-1.25 m.
During operation, the blade 1 is connected to the rotor 20. The seat of the rotor 20 housing the root 3 advantageously has tapering 21 at its borders, to reduce stress concentration at the blade 1.
During operation the rotor 20 rotates, causing rotation of the blades as well. The centrifugal forces push the blades radially outwards and the diverging portions 7 retain the blades 1; this causes a compression (as indicated by arrows P) of the diverging walls 7 with the risk of collapse. The reinforcing element 8 interposed between the diverging walls 7 supports the diverging walls 7 and counteracts the collapse.
Naturally the features described may be independently provided from one another. For example, the features of each of the attached claims can be applied independently of the features of the other claims.
In practice the materials used and the dimensions can be chosen at will according to requirements and to the state of the art.
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