The invention concerns an assembly for a turbine engine turbine.
More specifically, the invention relates to an assembly for a turbine engine turbine comprising a means for disengaging the turbine in the event of overspeed.
In a turbine engine, a fan is driven in rotation by a turbine having a rotor disc equipped with moving vanes and connected to a low pressure compressor. If a shaft connecting the fan to the turbine breaks, the resistive torque on the turbine is abruptly cancelled while the engine gas flow continues to transmit energy to the rotor disc. This causes an uncontrolled increase in the speed of the rotor disc(s) and thus a risk of bursting, resulting in the release of high energy flows. In this case, the turbine is in “overspeed”.
EP1640564 proposes a device that uses the downstream displacement of the turbine to limit the overspeed of the turbine. The device comprises means of destruction of the moving vanes arranged in downstream stator vanes of the turbine. However, downstream displacement of the rotor disc can be prevented by means of translational fixing of the turbine with respect to its axis of rotation. As a result, the moving vanes are not damaged by the means of destruction. Such devices therefore lack effectiveness and reliability in limiting overspeed.
One of the purposes of the invention is to ensure downstream movement of the turbine in the event of shaft failure so that an annular row of moving vanes comes into contact with an annular row of stator vanes, thereby allowing destruction of the annular row of moving vanes by the annular row of stator vanes, thus slowing down the turbine.
Another purpose of the invention is to limit the overspeed of the turbine in a reliable and efficient manner in the event of a shaft failure.
To this end, the invention proposes an assembly for a turbine engine turbine having a longitudinal axis comprising:
In one embodiment, the first means of transmitting torque may comprise first longitudinal splines formed on the shaft and distributed circumferentially around the longitudinal axis and second longitudinal splines engaging with the first splines and formed in an inner annular side of the rotor disc.
The first means of transmitting torque can cease to transmit torque from the rotor disc to the shaft if the first and/or second splines break or are damaged.
The second means of transmitting torque may comprise a ring centred on the longitudinal axis and comprising first pins cooperating with recesses formed in the screwed member and second pins cooperating with recesses formed in the rotor disc.
The first pins allow the screwed member to be rotated when the ring is rotated by the rotor disc through the second pins, for example when the first means of transmitting torque cease to transmit torque from the rotor disc to the shaft.
In one embodiment, the circumferential clearance between the first splines and the second splines may be less than the sum of the circumferential clearance between the second pins and the rotor disc and the circumferential clearance between the first pins and the screwed member.
Thus, the transmission of rotation from the rotor disc to the shaft is favoured and the screwed member is not rotated when the first means of transmitting are able to transmit rotation from the rotor disc to the shaft.
In one embodiment, the ring may comprise an annular section, with the first pins extending upstream and the second pins being arranged downstream from the first pins.
In addition, at least one of the first pins and of the second pins may comprise concave rounded portions for connection to the annular section. This allows for a better mechanical strength of the ring.
The second pins may extend mainly in the direction of the longitudinal axis. The second pins can extend downstream in the direction of the longitudinal axis.
The second pins may extend mainly in a radial direction perpendicular to the longitudinal axis.
The number of second pins may be greater than the number of recesses in the rotor disc.
The number of first pins may be greater than the number of recesses in the screwed member.
A number of pins greater than the number of recesses facilitates tight fitting of the ring to the rotor disc on the one hand and to the screwed member on the other hand.
The number of second pins may be less than the number of first pins.
The ring can be mounted in different ways. For example, the ring can be mounted around the screwed member. The ring can be locked in translation in the downstream direction by a circlip installed in a groove in the screwed member.
In one embodiment, an annular space may be provided immediately downstream from the screwed member. The annular space may have a longitudinal dimension greater than or equal to a longitudinal distance between moving vanes connected to the rotor disc and stator vanes immediately downstream from the turbine.
Thus, the turbine can be moved back far enough for the stator vanes to come into contact with vanes connected to the rotor disc.
The shaft can be connected to a low-pressure compressor of the turbine engine.
According to another aspect, the invention proposes a turbine, such as a low-pressure turbine, comprising the above-mentioned assembly.
In one embodiment, the turbine may extend around a longitudinal axis, and comprise a stator and a rotor rotatably mounted in the stator. The rotor may comprise an assembly as aforesaid, wherein the ring is lockable in translation downstream by a circlip installed in a groove in the screwed member.
An annular space may be arranged immediately downstream from the screwed member, wherein said annular space has a longitudinal dimension greater than or equal to a longitudinal distance between moving vanes connected to the rotor disc and stator vanes located immediately downstream from the moving vanes.
According to another aspect, the invention proposes a turbine engine, such as an aircraft turbojet engine, equipped with the above-mentioned assembly.
With reference to
The rotor disc 12 is held in translation in the direction of the axis of rotation A-A by a nut 22 screwed onto the shaft 14 and abutting against a flange 30 of the rotor disc 12. The nut 22 is mounted on the shaft 14 in such a way that its unscrewing direction is identical to the direction of rotation of the turbine 10. For this purpose, a thread is provided in the shaft 14 to ensure such an unscrewing direction.
If the shaft 14 or the connection between the shaft 14 and the rotor disc 14 fails, there is a risk that the turbine 10 will overspeed uncontrollably as a result of the hot gases from an upstream combustor driving the vanes in rotation. In order to limit overspeed, the convex protrusions 28 of the stator vanes 24 are arranged to shear and feather the moving vanes 26 to reduce or even cancel the energy received by the turbine 10. These protrusions are formed at the leading edge of the vanes. More particularly, the leading edge of each vane thus comprises a convex surface.
In order to ensure that the protrusions 28 contact the moving vanes 24, the turbine includes a ring 32 configured to unscrew the nut 22 in the event of damage to the shaft 14, thereby releasing the rotor disc 12 in translation in the direction of the axis of rotation A-A.
The ring 32 is annular and arranged between the nut 22 and the rotor disc 12. The ring 32 comprises first pins 34, distributed circumferentially around the axis of rotation A-A, engaging with recesses provided in the shaft 14. The ring 32 also comprises second pins 36, distributed circumferentially around the axis of rotation A-A, engaging with recesses provided in the rotor disc 12.
When the shaft 14 fails or the splines 16 and 18 are disengaged from each other, the ring 32 transmits the rotation of the rotor disc 12 to the nut 22. Thus, the nut 22 is unscrewed by the rotation of the turbine 10, which releases the turbine 10 in translation. The turbine 10 moves downstream along the axis of rotation A-A, causing the moving vanes 26 to be sheared off by the protrusions 28 of the stator vanes 24 downstream from the moving vanes 26.
The turbine 10 comprises a space downstream from the nut 22 having a length greater than the distance between the protrusions 28 of the stator vanes 24 and the moving vanes 26. For example, the length of said space may be greater than or equal to twice said distance. The circumferential clearance between the splines 16 of the rotor disc 12 and the splines 18 of the shaft 14 may be less than the sum of the circumferential clearance between the second pins 36 and the rotor disc 12 and the circumferential clearance between the first pins 34 and the nut 22.
In addition, an annular circlip 38 is arranged downstream from the ring 32 in a location provided in the nut 22 and projecting in the radial direction away from the nut 22. The circlip 38 keeps the ring 32 fixed in translation in the direction of the axis of rotation A-A.
The number of first pins 104 is less than the number of recesses in the nut 22 and the number of second pins 106 is less than the number of recesses in the rotor disc 12. This makes it easier to fit the ring 100 into the rotor disc 12 on the one hand and into the nut 22 on the other. For example, the number of recesses in the nut 22 may be equal to or greater than twice the number of first pins 104. The number of recesses in the rotor disc 12 may be twice the number of second pins 106. In addition, the number of first pins 104 may be less than the number of second pins 106.
Each of the first pins 104 has a rounded connection with the annular section 102. Similarly, each of the second pins 106 has a rounded connection with the annular section 102. This improves the mechanical strength of the ring 32.
The ring 100 furthermore has an annular shoulder 108 borne by the annular section 102 and bounded by the first pins 10, which shoulder 108 abuts upstream on an annular shoulder of the nut 22.
The ring 100 may be made of a material identical to the material of the nut 22 and/or the rotor disc 12.
The number of first pins 204 is less than the number of recesses in the nut 22 and the number of second pins 206 is less than the number of recesses in the rotor disc 12. This makes it easier to fit the ring 200 into the rotor disc 12 on the one hand and into the nut 22 on the other. For example, the number of recesses in the nut 22 may be equal to or greater than twice the number of first pins 204. The number of recesses in the rotor disc 12 may be twice the number of second pins 206. In addition, the number of first pins 204 may be less than the number of second pins 206.
Each of the first pins 204 has a rounded connection with the annular section 102. Similarly, each of the second pins 106 has a rounded connection with the annular section 202. This improves the mechanical strength of the ring 32.
Number | Date | Country | Kind |
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FR2000227 | Jan 2020 | FR | national |
Filing Document | Filing Date | Country | Kind |
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PCT/FR2021/050021 | 1/8/2021 | WO |