Assembly for controlling variable pitch vanes in a turbine engine

Abstract

An assembly for controlling variable pitch vanes in a turbine engine, the assembly comprising an actuating ring surrounding a casing of the turbine engine and connected by rods to variable pitch vanes. The actuating ring is configured to rotate around the casing. The assembly further includes a passive element including a first end sliding connected to a second end. The first end is connected by a sliding pivoting link on the actuating ring, and the second end is connected by a ball-joint link to the casing.

Claims

1. An assembly for controlling variable pitch vanes in a turbine engine, the assembly comprising: an actuating ring surrounding a casing of the turbine engine and connected by rods to variable pitch vanes; driving means for rotating the actuating ring around the casing; and a passive element including a first end slidingly connected to a second end, wherein the first end of the passive element is connected by a sliding pivoting link on the actuating ring, and wherein the second end of the passive element is connected by a ball-joint link to the casing.

2. The assembly of claim 1, wherein the passive element is arranged circumferentially substantially opposite the driving means of the actuating ring.

3. The assembly of claim 1, wherein the passive element comprises a body bearing the first end and in which a pin bearing the second end is mounted for translational movement.

4. The assembly of claim 1, wherein the first end of the passive element is mounted for rotation and translational movement around and according to a radial axis in a yoke of a first support element integral with the actuating ring.

5. The assembly of claim 4, wherein the second end of the passive element is connected via the ball-joint link to a second support element integral with the casing.

6. The assembly of claim 5, wherein the first support element is arranged axially downstream, or upstream respectively, from the rods and the second support element is arranged upstream, or downstream respectively, from the rods.

7. The assembly of claim 1, wherein the second end of the passive element is connected via a flange of the casing.

8. The assembly of claim 1, wherein the passive element is a braking cylinder.

9. The assembly of claim 8, wherein the braking cylinder is a gas cylinder or a spring loaded cylinder.

10. A turbine engine comprising the assembly of claim 1.

11. The assembly of claim 1, wherein the first end comprises a body of a cylinder, and wherein the second end comprises a pin mounted in the body of the cylinder.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) The invention will be better understood and other details, characteristics, and advantages of the invention will appear on reading the following description given by way of non-limiting example and with reference to the accompanying drawings, in which:

(2) FIG. 1 is a side view of a turbine engine comprising a casing on which rings for controlling variable pitch vanes and driving means for rotating these rings are mounted;

(3) FIG. 2 is a front view of the turbine engine in FIG. 1;

(4) FIG. 3 is a side view showing a ring during normal movement and in dotted lines, a ring having undergone deflection;

(5) FIG. 4 is a detailed top perspective view of an assembly according to the invention comprising a casing, variable pitch vanes, a vane pitch actuating ring, connected to the vanes by rods and a cylinder in order to restrict the axial displacement of the ring on the casing;

(6) FIG. 5 is a simplified view of the assembly in FIG. 4 in which the vanes have been angularly pitched;

(7) FIG. 6 is a diagrammatic sectional view representing the cylinder of the assembly in FIGS. 4 and 5;

(8) FIG. 7 is a diagrammatic view representing the cylinder in FIG. 4 in three different positions.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

(9) Illustrated in the figures is an assembly 2, particularly for controlling variable pitch vanes 4 in a turbine engine 6, comprising a casing 8 of the turbine engine 6, an actuating ring 10 surrounding the casing 8 and connected by rods 12 to the variable pitch vanes 4 and a driving means 14 for rotating the actuating ring 10 around the casing 8. Preferably, the casing 8 is annular and has a longitudinal axis A of symmetry and the actuating ring 10 is coaxial with the casing 8 and mounted around the latter. In the example illustrated in the figures and particularly in FIG. 1, two rings 10 are represented; however, reference will only be made to a single ring 10 in the further description, given that all the actuating rings 10 are identical and function in the same manner.

(10) The casing 8 has shafts 16 in which nuts 18 integral with the vanes 4 are fixed, said nuts 18 defining an axis A1 of rotation of the vanes 4 to adjust their pitch.

(11) The rods 12 are integral at a first end 20 with the nuts 18 of the vanes 4, and at a second end 22 with the actuating ring 10. However, it should be explained that the link between the rods 12 and the actuating ring 10 is a ball-joint link permitting a rotational movement between the rods 12 and the actuating ring 10.

(12) Hence, when the actuating ring 10 is driven in rotation by the driving means 14 for rotation, the rods 12 pivot relative to the ring and are forced by their second end 22 to follow the actuating ring 10, such that as a result of their solid attachment to the nuts 18 of the vanes 4, the movement of the rods 12 implies rotation of the vanes 4 around their respective axis A1.

(13) Preferably, the assembly 2 comprises, for each actuating ring 10, a single driving means 14 that comprises in particular a first support 24 integral with an actuating ring 10, a second support 26 integral with the casing 8 and an actuator 28, in the present case a cylinder, mounted for rotation, by both ends, on each of the first support 24 and the second support 26. When the actuator 28 is operated, it induces a rotational movement to the actuating ring 10 around the longitudinal A of the casing 8 which, as explained above, causes rotation of the vanes 4 by means of the rods 12.

(14) It is therefore understood that a single driving means 14 is used for each actuating ring 10. This particularly allows a reduction in the overall dimensions of the assembly 2 and restriction of the weight of this assembly 2.

(15) Reference will now be made to FIG. 3.

(16) Movement of the actuating ring 10 during pitch adjustment of the vanes 4 is then a combination of a rotation around the longitudinal axis A, caused by the driving means 14 and a translational movement T along the same longitudinal axis A, caused by the rods 12 which are non-deformable.

(17) The presence of a single driving means 14 for each ring and the combined movement of the actuating ring 10 subsequently causes deflection of the actuating ring 10. Deflection is defined as uncontrolled deformation of the actuating ring 10; in the present case twisting of the actuating ring 10. It will be noticed, via the illustration of the actuating ring 10 in dotted lines in FIG. 3, that the deflection is maximum in a portion radially opposite the first support 24 integral with the actuating ring 10. This maximum deflection is the result of the axial movement of the rods 12, which tend to cause axial displacement of the actuating ring 10 to a greater extent than necessary, particularly owing to the non-deformability of the rods 12. On contrary, the deflection of the actuating ring 10 is zero or almost zero at the level of the driving means 14 that guides the actuating ring 10 in its displacement. Hence, it appears obvious that doubling the number of driving means 14, by placing the latter opposite each other, would be a solution to be considered for limiting the deflection of the actuating ring 10; however, use of two driving means 14 increases the weight of the turbine engine and above all increases the overall dimensions of the assembly 2.

(18) In FIG. 3, the ring 10 in the so-called normal position, i.e. without deflection, is referenced 10a and the deflected ring 10 is referenced 10b.

(19) As can be seen in FIGS. 4 and 5, the assembly 2 comprises a slidingly connected element 30. As illustrated in the figures, the slidingly connected element 30 is in the present case a passive cylinder 30, hereinafter known as cylinder 30, the first end of which 32 is connected by a sliding pivoting link to the actuating ring 10 and a second end 34 is connected by a ball-joint link on the casing 8, around axes A2, A3 respectively, which are substantially radial, passing through the first end 32 and the second end 34 respectively. It should be understood that the axes A2, A3 are radial when the rods 12 are substantially parallel to the axis A of the turbine engine 6.

(20) Passive means that the cylinder 30 is not governed or controlled.

(21) The cylinder 30 is in this case circumferentially opposite the driving means 14 in order to limit deflection of the actuating ring 10 as will be seen below. This cylinder 30 subsequently serves to limit the axial deflection of the actuating ring 10 on the casing 8 to the axial displacement induced by the actuator 28, i.e. the driving cylinder. When the actuating ring 10 is driven in rotation, any deflection is counteracted by the translational displacement of the pin 38 in the body 36 of the cylinder 30 such that the deflection is halted. The cylinder 30 comprises a body 36 bearing the first end 32 and in which a pin 38 bearing the second end 34 is mounted for translational movement.

(22) As can be seen in further detail in FIG. 6, the first end 32 of the cylinder 30 is mounted in a sliding pivoting link in a yoke 40 of a first support element 42 integral with the actuating ring 10 and the second end 34 of the cylinder 30 is connected by a ball-joint link 44 to a second support element 46 integral with the casing 8.

(23) The ball-joint link 44 allows the cylinder 30 to follow the movement of the actuating ring 10. Indeed, given that the cylinder 30 is integral with the actuating ring 10 at a fixed point, the path of the first end 32 of the cylinder 30 is a combination of a translational movement T along the longitudinal axis A and a rotational movement around the longitudinal axis A. The ball-joint link 44 thereby makes it possible to avoid any hyperstatism of the cylinder 30, which would be detrimental to its functioning and might cause its breakage in a worst-case scenario.

(24) Advantageously, the first support element 42 is arranged axially downstream (or upstream respectively) from the rods 12 and the second support element 46 is arranged upstream (or downstream respectively) from the rods 12. It should be explained that axially means in an axial direction, i.e. along the longitudinal axis A.

(25) Such an arrangement allows in particular a gain in compactness of the assembly 2 and a gain in weight, since the cylinder 30 is passive, therefore simpler in terms of design and production and of lower weight than a controlled cylinder.

(26) The support elements 42, 46 are separate parts on the casing 8 and the actuating ring 10 and are secured in particular by means of bolts 48, i.e. by a nut and screw assembly, by riveting or by welding for example.

(27) Advantageously, the second support element 46 is integral with a flange 50 of the casing 8.

(28) FIG. 7 shows, diagrammatically, the position of the passive cylinder 30 for a maximum spacing position of the actuating ring 10 in relation to the casing 8 and in dotted lines, two positions of the cylinder 30 for a minimum spacing position of said actuating ring 10.

(29) When the actuating ring 10 is in the maximum spacing position, the vanes 4 are in an angular orientation suitable for the majority of phases of use of the turbine engine and the rods 12 are substantially parallel to the longitudinal axis 1. For some phases of use of the turbine engine, the vanes 4 need to have a specific orientation ranging to a maximum orientation in which the cylinder 30 of the assembly forms an angle with the longitudinal axis A. The angular coverage of the cylinder 30 is therefore equal to 2, i.e. the displacement on each side of the longitudinal axis A. Preferably, is between 30 in opening and +30 in closing.

(30) It should be noted that in the majority of cases, the cylinder 30 is substantially parallel to the longitudinal axis A.

(31) According to one aspect, the cylinder 30 is a gas braking cylinder or spring loaded braking cylinder inhibits the inwards and outwards movements of the pin 38 in the body 36 so as to limit deformation of the ring 10 when the latter is moved by the actuator 28. In the case of a spring-loaded cylinder, the tension of the spring will be selected accordingly in order to adjust the speed of movement of the pin 38 of the cylinder 30 in relation to the body 36, in order to allow axial displacement of the actuating ring 10 while controlling the latter. In contrast, in the case of a gas cylinder, it is the gas discharge valves of the body 36 of the cylinder 30 that will determine the speed of movement of the pin 38 in relation to the body 36.

(32) During operation of the turbine engine, when the driving means 14 are activated, the actuator 28 causes the actuating ring 10 to rotate around the longitudinal axis A and the actuating ring 10 subsequently drives in turn the rods 12 that rotate the vanes 4.

(33) In rotating around the axis A1 of the nuts 18 of the vanes 4, the rods 12 tend to move the actuating ring 10 uncontrollably in relation to the movement caused by the driving means 14. The cylinder 30 serves in this case to control the movement of the actuating ring 10 such that translation along the longitudinal axis A is substantially identical at all points of the actuating ring 10.

(34) Hence, there is no deflection of the actuating ring 10 and therefore no risk of breakage of the actuating ring 10 nor any need for preventive or curative maintenance on the entire turbine engine 6.

(35) Furthermore, use of a cylinder 30 makes it possible to limit the overall dimensions of the assembly 2 and therefore of the turbine engine 6 in relation to use of a second driving means 14 circumferentially opposite the first.