FR3139854A1 - Inter-turbine casing - Google Patents

Abstract

Inter-turbine casing for a turbomachine of the vane frame turbine type fulfilling the function of turbine distributor in such a turbomachine, comprising an internal shroud (9), an external shroud, a plurality of arms (11) extending between the internal shroud ( 9) and the external shroud, and at least one set of N separator vanes (12) positioned circumferentially between two successive arms (11), each separator vane (12) having an axial chord at mid-height shorter than the axial chord at mid-height of the arms (11), in which said two successive arms (11) define a reference position for each of said N separating vanes (12), these reference positions being regularly spaced circumferentially between the two successive arms (11), and in which at least one separator vane (12-1) of said set of N separator vanes (12) is offset circumferentially relative to its reference position. Fig. 3.

Description

Inter-turbine casing

The present presentation generally concerns an inter-turbine casing for a turbine vane frame type turbomachine (TVF, for turbine blade structure) fulfilling the function of turbine distributor in such a turbomachine.

In a manner known per se, a turbomachine comprises an inter-turbine casing arranged between the high pressure turbine casing and the low pressure turbine casing in a turbomachine. The inter-turbine casing comprises a fairing (or fairing in English) comprising an internal shroud and an external shroud, which together delimit the flow path between the high-pressure turbine and the low-pressure turbine, as well as arms which extend radially between the internal ferrule and the external ferrule.

The inter-turbine casing has both an aerodynamic function, as a stator making it possible to deflect the incident flow coming from the high pressure turbine, a structural function to transmit mechanical forces between the internal shroud and the external shroud, and a integration function for the passage of easements. The fairing can therefore have a multi-profile configuration and include, in addition to the arms, separator vanes (or “splitters” in English) which have a reduced chord size in comparison with the arms, which are thicker and have a larger chord. long. The separating vanes and the downstream part of the arms thus ensure the aerodynamic function, while the arms ensure the structural and integration functions.

However, the wakes generated by the blades of the inter-turbine casing (i.e. the thick arms and the splitter blades) are particularly wide and energetic. In particular, the significant differences in profile between the arms and the separating blades lead to significant differences in wakes which lead to the appearance of significant distortions in the flow downstream of the inter-turbine casing, these distortions being likely to disrupt the performances. of the low pressure turbine (aerodynamic losses, appearance of separations), impact its mechanical strength (periodic excitations) or even pose problems of integration of the low pressure turbine (size of the low pressure turbine).

There is therefore a real need to remedy the aforementioned drawbacks, by proposing a solution making it possible to improve the aerodynamic efficiency and therefore the efficiency of the low pressure turbine in a turbomachine comprising an inter-turbine casing.

This presentation concerns an inter-turbine casing for a turbomachine, comprising
an internal shell, centered on a central axis,
an external shell, surrounding the internal shell in a coaxial manner,
a plurality of arms, each arm extending between the inner shell and the outer shell, having a leading edge and a trailing edge and having an axial chord at mid-height, and
at least one set of N separator vanes positioned circumferentially between two successive arms, each separator vane extending between the internal shroud and the external shroud, having a leading edge and a trailing edge and having an axial chord at mid-height shorter than the axial chord at mid-height of the arms,
in which said two successive arms define a reference position for each of said N separating vanes, these reference positions being regularly spaced circumferentially between the two successive arms, and
in which at least one separator vane of said set of N separator vanes is offset circumferentially relative to its reference position.

In other words, in the reference configuration, the azimuth A_iof the reference position of the i^e separating blade of said set of N separating blades, that is to say its angular position around the central axis, can be written as follows A_i=A_B1+ (A_B2-HAS_B1)/(N+1), with A_B1the azimuth of the first arm and HAS_B2the azimuth of the second arm delimiting said set of N separating blades.

Thus, in such a configuration according to the invention, unlike the conventional configuration that is usually found in rotating machines, the separator blades are not all arranged regularly between the arms.

Indeed, the inventors noted that this reference configuration according to which the arms and the separating blades are regularly spaced around the central axis generated significant distortions in flow rate and orientation of the flow passing through the inter-turbine casing. Conversely, the inventors determined that shifting all or part of the separator blades from their commonly accepted reference positions made it possible to reduce flow distortions, and therefore to increase the performance of the downstream turbine.

Thus, the invention is the result of technological research aimed at significantly improving the performance of turbomachines and, in this sense, contributes to reducing the environmental impact of the aeronautics sector.

In some embodiments, the plurality of arms includes between 4 and 20 arms.

In certain embodiments, the arms are distributed regularly around the central axis. Their distribution is therefore axisymmetric.

In certain embodiments, all the arms have the same profile.

In certain embodiments, at least one arm is hollow, said at least one arm comprising a passage allowing the passage of an easement of the turbomachine.

In certain embodiments, said set of N separator vanes comprises between 1 and 4 separator vanes.

In certain embodiments, the inter-turbine casing comprises a set of separator vanes between each successive arm.

In some embodiments, each set of splitter vanes includes the same number of splitter vanes.

In some embodiments, the separator vanes are arranged in the same manner, relative to each other, in each set of separator vanes. Thus, the configuration of each set of separating blades, that is to say the combination of the respective arrangements of each of their blades, constitutes the same pattern which is repeated identically between arms.

In certain embodiments, all the separator vanes have the same profile.

In certain embodiments, the axial chord at mid-height of the separator vanes is at least 2 times shorter, preferably at least 3 times shorter, than the axial chord at mid-height of the arms.

In certain embodiments, the maximum thickness of the separator vanes is less than the maximum thickness of the arms.

In certain embodiments, the maximum thickness of the separating vanes is at least 2 times shorter, preferably at least 3 times shorter, than the maximum thickness of the arms.

In certain embodiments, the profile of at least one downstream portion of the separator vanes is identical to the profile of a downstream portion of the arms. The aerodynamic behaviors of the arms and the separating vanes are thus analogous, at least near their trailing edges, which reduces flow distortions.

In some embodiments, the trailing edges of the splitter vanes are aligned circumferentially around the central axis with the trailing edges of the arms.

In certain embodiments, the leading edges of the separator vanes are arranged further downstream than the leading edges of the arms.

In certain embodiments, at least one separator vane of said set of N separator vanes adjacent to an arm is offset circumferentially relative to its respective reference position. This is preferably the case for the two clearance separating vanes adjacent to an arm. This helps reduce distortions caused by the difference in arm profile.

In certain embodiments, all the separator vanes of said set of N separator vanes are offset circumferentially relative to their respective reference positions.

In certain embodiments, the circumferential offset of said at least one separator blade which is offset circumferentially relative to its reference position is less in absolute value than 0.25 x Δref, where Δref is the angular difference between two positions of consecutive references. Preferably, no separator blade has a circumferential offset relative to its reference position greater, in absolute value, than this ceiling. Indeed, the inventors determined that the optimal offset zone was located in this range.

In certain embodiments, at least one separator vane of said set of N separator vanes has a thickness different from the other separator vanes of said set of N separator vanes. Consequently, in such a case, the stacking in trace BF (trailing edge) of the cross sections of the blade in question does not overlap with the stacking in trace BF of the cross sections of the arm.

In certain embodiments, at least one separator vane of said set of N separator vanes has a different geometry, in particular by presenting a different stacking law, from the other separator vanes of said set of N separator vanes. Likewise, in such a case, the stacking in trace BF (trailing edge) of the cross sections of the blade in question does not overlap with the stacking in trace BF of the cross sections of the arm.

This presentation also concerns a turbomachine assembly, comprising
an inter-turbine casing according to any of the preceding embodiments, and
a turbine extending downstream of the inter-turbine casing and comprising at least one moving blade extending radially.

The present presentation also relates to a turbomachine, comprising a turbomachine assembly according to any of the preceding embodiments.

The present presentation also relates to a method of positioning a separator blade within an inter-turbine casing according to any of the preceding embodiments, comprising the following steps:
provide an inter-turbine casing,
position separator blades within the inter-turbine casing in their respective reference positions;
evaluate a parameter of the flow passing through the inter-turbine casing on either side of a given splitter blade and determine a reference distortion of this parameter;
move said given separator vane into one or more azimuthal positions offset circumferentially relative to its reference position; And
for each of these shifted azimuthal positions:
- evaluate said parameter of the flow on either side of the given separating vane (12-1),
- determine the distortion (Dd') of this parameter, and
- compare the distortion after displacement (Dd') with the reference distortion (Dd),
positioning the separator vane within the inter-turbine casing at an offset azimuthal position which reduces the distortion of said flow parameter.

We understand here that the steps of positioning, moving and evaluating the parameter can be carried out experimentally or numerically using a digital simulation. We then retain for the given separating vane an offset position which makes it possible to reduce, or even minimize, the distortion of the flow parameter.

In some embodiments, the flow parameter is evaluated as a function of the azimuthal position in a downstream radial plane.

In certain embodiments, the step of evaluating the flow parameter after displacement is carried out for several different offset positions of the given separating vane within an exploration range.

In certain embodiments, the exploration range has an amplitude greater than 0.1 x Δref and less than 0.25 x Δref, where Δref is the angular difference between two consecutive reference positions.

In certain embodiments, these steps are repeated successively for each separator vane of said set of N separator vanes.

In some embodiments, the flow parameter evaluated is the rate of flow or the angle of the flow relative to the central axis.

In this presentation, the terms “longitudinal”, “transverse”, “lower”, “upper” and their derivatives are defined in relation to the main direction of the blades; the terms “axial”, “radial”, “tangential”, “interior”, “exterior” and their derivatives are defined in relation to the central axis of the inter-turbine casing, that is to say the the main axis of the turbomachine; we mean by “axial plane” a plane passing through the main axis of the turbomachine and by “radial plane” a plane perpendicular to this main axis; the terms “upstream” and “downstream” are defined in relation to the circulation of the air in the turbomachine; finally, the terms “front” and “back” are understood in the circumferential direction when progressing clockwise.

The aforementioned characteristics and advantages, as well as others, will appear on reading the detailed description which follows, of examples of embodiment of the inter-turbine casing and of the method proposed. This detailed description refers to the accompanying drawings.

The accompanying drawings are schematic and aim above all to illustrate the principles of the presentation.

In these drawings, from one figure to another, identical elements (or parts of elements) are identified by the same reference signs.

There is an axial sectional plan of a turbomachine according to the invention.

There is a sectional view of a turbomachine assembly comprising an example of an inter-turbine casing and a turbine.

There is a partial perspective view of the example of a turbomachine assembly of the .

There is a graph representing flow rate as a function of azimuthal position for a reference configuration and an offset configuration.

There is a graph representing the flow angle as a function of azimuthal position for the reference configuration and the offset configuration of the .

In order to make the presentation more concrete, an example of an inter-turbine casing is described in detail below, with reference to the attached drawings. It is recalled that the invention is not limited to this example.

A dual-flow turbomachine 1 (typically, an aircraft turbomachine 1) generally comprises, from upstream to downstream in the direction of gas flow, a fan 2, an annular primary flow vein I and an annular vein secondary flow II. The mass of air sucked in by the fan 2 is thus divided into a primary flow, which circulates in the primary flow vein I, and into a secondary flow, which is concentric with the primary flow and circulates in the flow vein secondary II.

The primary flow path I passes through a primary body comprising one or more stages of compressors, for example a low pressure compressor 3 and a high pressure compressor 4, a combustion chamber 5, one or more stages of turbines, for example a turbine high pressure 6 and a low pressure turbine 7 separated by an inter-turbine casing 8, and a gas exhaust nozzle.

In the present application, the upstream and downstream are defined in relation to the normal flow direction of the gases in the turbomachine 1. Furthermore, we call axis X, the axis of rotation of the rotor of the low pressure turbine 7 , which coincides with the axis of extension of the turbomachine 1. An axial direction corresponds to the direction of the axis X, a radial direction is a direction perpendicular to this axis X and passing through it. Furthermore, a circumferential direction corresponds to a direction perpendicular to the X axis and not passing through it.

The inter-turbine casing 8 comprises an internal shroud 9 and an external shroud 10 substantially coaxial with the axis X, and a fixed blade comprising a plurality of arms 11 together forming a crown. The arms 11 extend from the internal ferrule 9 to the external ferrule 10 and can be substantially radial with respect to the axis 9 and the external shell 10, which is housed in an aerodynamically shaped wall.

The aerodynamic wall thus makes it possible to straighten the flow at the outlet of the high pressure turbine 6 and to improve the supply to the low pressure turbine 7, which is located immediately downstream of the inter-turbine casing 8.

The inter-turbine casing 8 may in particular comprise between four and twenty arms 11. In this example, the inter-turbine casing 8 comprises ten arms 11. Preferably, these arms 11 are regularly spaced around the axis -turbine 8 also comprises a plurality of separator vanes 12 positioned circumferentially between the arms 11: a set of one or more separator vanes 12 is thus provided between each arm 11. It will be noted that, conventionally, the chord of each vane separator 12 is shorter than the chord of each arm 11. The trailing edge 12f of each separator vane 12 is aligned circumferentially with the trailing edge 11f of each arm 11; consequently, the leading edges 11a of the arms 11 are positioned more upstream than the leading edges 12a of the separating vanes 12. Furthermore, preferably, the downstream part of the arms 11 has a profile corresponding to at least one part downstream of the separating vanes 12.

The inter-turbine casing 8 can include between one and four separator blades 12 between successive arms 11. Preferably, each set of separator vanes 12 comprises the same number of vanes 12. In the present example, three separator vanes 12 are thus provided between each arm 11.

The low pressure turbine 7 comprises, in a manner known per se, a plurality of turbine stages each comprising at least one moving blade 13. The low pressure turbine 7 may comprise at least three turbine stages, for example between three and five stages turbine in the case of a turbomachine whose fan 2 is driven via a reduction mechanism. The low pressure turbine 7 being conventional, it will not be further detailed here.

Each arm 11 has an axial chord at mid-height 14. The axial chord at mid-height 14 of a given arm 11 is defined from a line at half-height 15, which corresponds to the (fictitious) line included in a plane perpendicular to the axis The mid-height line 15 of a given arm 11 extends axially from the trailing edge of the row of fixed blades of the last stage of the high pressure turbine 6 immediately upstream of the inter-turbine casing 8 up to the leading edge 12a of the moving blade 12 of the low pressure turbine 7 located immediately downstream of the inter-turbine casing 8. The axial chord at mid-height 13 then corresponds to the length of the straight line segment connecting points A and B, which correspond respectively to the projection on the axis intersection between the mid-height line 15 and the trailing edge 11f of arm 11.

Analogously, each separating blade 12 has an axial chord at mid-height measured by projecting onto the axis separator 12, and at the intersection between the mid-height line 15 and the trailing edge 12f of the separator blade 12.

Finally, the arm-blade distance 16 corresponds to the axial distance, measured at mid-height of the arm 11, between the trailing edge 11f of the arm 11 and the leading edge 13a of a movable blade 13 immediately downstream of the arm 11, that is to say the length of the line segment connecting points B (defined above) and C, where point C corresponds to the projection on the X axis of point C' located at the intersection between the mid-height line 15 and the leading edge 13a of the moving blade 13. It will be noted here that the arm-blade distance 16 can be measured for any moving blade 13 of the most advanced stage. upstream of the low pressure turbine 7 (generally designated as "first stage" of the low pressure turbine), insofar as the moving blades 13 are symmetrical in revolution around the axis mobile 13 selected in this stage, the projection on the axis

From then on, we define the downstream plane TVF 17, which is the plane perpendicular to the axis

An example of a method for positioning the separator vanes 12 will now be described.

This method aims to adjust the azimuth, that is to say the angular position around the axis that is to say the same combination of azimuths for each of their separating vanes 12: in other words, the i ^th separating vane 12 of a set is always located at the same angular distance from the arm 11 preceding it. Therefore, in this example, the method focuses on adjusting the azimuth of the separator vanes 12 of a single given set then the combination of azimuths obtained for this set will be reproduced identically for the other sets.

This being specified, a reference position is first calculated for each separating vane 12 of the set considered. This reference position corresponds to the position that the separator vane 12 would have in the classic configuration of equi-distribution around the axis the separator vanes 12 or between a separator vane 12 and its adjacent arm 11 is always equal. In the present example, with ten arms 11 and three separator vanes 12 per arm 11, we can calculate that this regular gap is equal to 360°/(10x(3+1)) = 9°. Therefore, if the arm 11 preceding the set of separating vanes 12 considered in the clockwise direction has the azimuth 0°, the reference position of the ^1st separating vane 12-1 will be 9°, the reference position of the ^2nd separator vane 12-2 will be 18°, and the reference position of the ^3rd separator vane 12-3 will be 27°.

A digital simulation, or an experiment on a test bench, is then carried out in the reference configuration in order to measure the flow rate passing through the inter-turbine casing 8 as a function of the azimuthal position in the downstream plane TVF 17 , at least along the angular sector separating the two arms 11 framing the set of separating vanes 12 considered. We then obtain a curve 21 as represented on the graph of the (this graph is represented here partially, centered on the first dawn 12-1 of the game considered since it is the first dawn that we will seek to position).

On this curve 21, it should be understood that the minimum 21a corresponds to the reduction of the flow in the extension of the arm 11, while the minimum 21b corresponds to the reduction of the flow in the extension of the first blade 12-1, which allows you to identify the latter. We also note that the presence of arm 11 and blade 12-1 respectively causes flow peaks 21c and 21d on their intrados side. In addition to these extrema 21a-21d directly caused by the presence of the arms 11 and the separating blades 12, we note the presence of a local maximum 21e followed by a local minimum 21f between the arm 11 and the first blade 12-1, as well that the presence, in an analogous manner, of a local maximum 21g followed by a local minimum 21h ahead of the first dawn 12-1 clockwise.

The flow distortion Dd between the front and the rear of the blade 12-1, constituting a reference distortion, is then measured between the maximum flow rate 21e behind the first blade 12-1 in the clockwise direction and the minimum flow 21 hours before the first dawn 12-1 clockwise.

The first blade 12-1 is then moved forward and/or backward from its reference position, preferably in a range deviating from a maximum of 0.25 times the normal angular deviation, i.e. 0.25x9° = 2, 25° in this example. Thus, in this example, several positions can be tested for the first blade 12-1 between azimuth 6.75° and 11.25°.

For each position tested, a digital simulation or an experiment on a test bench is again carried out in order to measure the flow rate passing through the inter-turbine casing 8 as a function of the azimuthal position in the downstream plane TVF 17, at least on either side of the first dawn 12-1. We then obtain the curve 22 as represented on the graph of the .

We then find extrema 22a-22h similar to those of curve 21 of the reference configuration but whose positions are offset. In particular, we note that the minimum 22b and the maximum 22d are shifted forward in the clockwise direction, which reveals that the blade 12-1 has been moved forward in the clockwise direction relative to its position reference.

Analogously to what was done for the reference configuration, we then measure in this shifted configuration the flow distortion Dd' between the maximum flow rate 22e behind the first blade 12-1 and the minimum flow rate 22h in before the first dawn 12-1. We then see that the offset of the blade 12-1 made it possible to significantly reduce this flow distortion Dd’.

It is then possible to retain the tested position which makes it possible to minimize the flow distortion Dd’. Then, once the optimal position of the first blade 12-1 has been determined, the same steps can be carried out to determine the optimal position of the second blade 12-2 by focusing on the flow distortion between the rear and the 'before the second dawn 12-2. And so on for all the separating vanes 12 in the game.

Alternatively, or in addition, it is also possible to carry out these positioning based on another parameter of the flow and in particular the angle of the flow relative to the axis downstream plane TVF 17, as shown on the .

Thus, curve 31 of the represents the curve of the flow angle as a function of the azimuthal position in the downstream plane TVF 17 in the reference configuration, while curve 32 represents the curve of the flow angle in the offset configuration.

On these curves, the minima 31a and 32a make it possible to identify the arm 11 while the minima 31b, 32b make it possible to identify the first blade 12-1. The distortion of the flow angle Da, Da' is measured between the maximum 31e, 32e behind the first blade 12-1 and the maximum 31h, 32h ahead of the first blade 12-1, in the direction hourly. It can thus be noted that the offset of the first blade 12-1 made it possible to significantly reduce the angle distortion Da' compared to the angle distortion Da in the reference configuration.

In a variant embodiment, in addition to a circumferential offset of at least one separator blade, it is also possible to modify the thickness of a separator blade. This modification can equally concern a blade offset circumferentially as well as a blade which has not been offset circumferentially.

In another alternative embodiment, in addition to a circumferential offset of at least one separator blade, it is also possible to modify the stacking law of a separator blade. This modification can equally concern a blade offset circumferentially as well as a blade which has not been offset circumferentially.

Although the present invention has been described with reference to specific embodiments, it is evident that modifications and changes can be made to these examples without departing from the general scope of the invention as defined by the claims. In particular, individual features of the different illustrated/mentioned embodiments can be combined in additional embodiments. Therefore, the description and drawings should be considered in an illustrative rather than a restrictive sense.

It is also obvious that all the characteristics described with reference to a process can be transposed, alone or in combination, to a device, and conversely, all the characteristics described with reference to a device can be transposed, alone or in combination, to a process.

Claims (12)

Inter-turbine casing for turbomachine, comprising
an internal ferrule (9), centered on a central axis (X),
an external ferrule (10), surrounding the internal ferrule (9) coaxially,
a plurality of arms (11), each arm (11) extending between the internal ferrule (9) and the external ferrule (10), having a leading edge (11a) and a trailing edge (11f) and having an axial chord at mid-height (14), and
at least one set of N separator vanes (12) positioned circumferentially between two successive arms (11), each separator vane (12) extending between the internal shroud (9) and the external shroud (10), having an edge of attack (12a) and a trailing edge (12f) and having an axial chord at mid-height shorter than the axial chord at mid-height (14) of the arms (11),
in which said two successive arms (11) define a reference position for each of said N separating vanes (12), these reference positions being regularly spaced circumferentially between the two successive arms (11), and
in which at least one separator vane (12-1) of said set of N separator vanes (12) is offset circumferentially relative to its reference position. Inter-turbine casing according to claim 1, in which the arms (11) are distributed regularly around the central axis (X). Inter-turbine casing according to claim 1, in which at least one arm (11) is hollow, said at least one arm (11) comprising a passage allowing the passage of an easement of the turbomachine (1). Inter-turbine casing according to any one of claims 1 to 3, comprising a set of separating vanes (12) between each successive arm (11),
in which each set of separator vanes (12) comprises the same number of separator vanes (12), and
wherein the separator vanes (12) are arranged in the same manner, relative to each other, in each set of separator vanes (12). Inter-turbine casing according to any one of claims 1 to 4, in which the profile of at least one downstream portion of the separating blades (12) is identical to the profile of a downstream portion of the arms (11), and
in which the trailing edges (12f) of the separator vanes (12) are aligned circumferentially around the central axis (X) with the trailing edges (11f) of the arms (11). Inter-turbine casing according to any one of claims 1 to 5, in which all the separator vanes (12) of said set of N separator vanes (12) are offset circumferentially relative to their respective reference positions. Inter-turbine casing according to any one of claims 1 to 6, in which the circumferential offset of said at least one separator blade (12-1) which is circumferentially offset relative to its reference position is less in absolute value than 0 .25 x Δref, where Δref is the angular difference between two consecutive reference positions. Inter-turbine casing according to any one of claims 1 to 7, in which at least one separator vane of said set of N separator vanes (12) has a thickness different from the other separator vanes of said set of N separator vanes (12). Inter-turbine casing according to any one of claims 1 to 7, in which at least one separator vane of said set of N separator vanes (12) has a different geometry, in particular by presenting a different stacking law, from the other separator vanes. of said set of N separating vanes (12). Turbomachine assembly, including
an inter-turbine casing (8) according to any one of the preceding claims, and
a turbine (7) extending downstream of the inter-turbine casing (8) and comprising at least one movable blade (13) extending radially. Turbomachine, comprising a turbomachine assembly (7-8) according to the preceding claim. Method of positioning a separator blade within an inter-turbine casing according to any one of claims 1 to 9, comprising the following steps:
provide an inter-turbine casing
position separator vanes (12) within the inter-turbine casing in their respective reference positions;
evaluate a parameter of the flow passing through the inter-turbine casing (8) on either side of a given separating blade (12-1) and determine a reference distortion (Dd) of this parameter;
move said given splitter vane (12-1) into one or more azimuthal positions offset circumferentially relative to its reference position; And
for each of these shifted azimuthal positions:
- evaluate said parameter of the flow on either side of the given separating vane (12-1),
- determine the distortion (Dd') of this parameter, and
- compare the distortion after displacement (Dd') with the reference distortion (Dd),
positioning the separator vane within the inter-turbine casing at an offset azimuthal position which reduces the distortion of said flow parameter.