EP3341570B1 - Device for attaching manifolds for cooling the casing of a turbine-engine turbine by air jets - Google Patents

Description

GENERAL TECHNICAL FIELD

The invention lies in the field of cooling a turbine casing, in particular a low pressure turbine, a turbomachine.

The present invention more specifically relates to a device for fixing air jet cooling ramps of the casing of a turbine of a turbomachine.

The invention also relates to a turbomachine equipped with such a device.

STATE OF THE ART

As can be seen on the Figures 1 and 2 Attached, which represent the state of the art, the low-pressure turbine of a turbomachine is protected by a housing C generally flared, substantially frustoconical. This housing is cooled using impact cooling technology.

The casing C is equipped with one or more box (es) B of pressurized air supply, connected to several cooling ramps R.

In the embodiment shown in the figures, the housing C is equipped with two housings B, positioned at about 180 ° from each other (only one being visible on the figure 2 ). Each box B is equipped with five ramps R, with two tubes T by ramps, each tube extending about 90 °. The tubes T are pierced with a series of small openings opening to the right of the outer surface of the housing. The pressurized air passing through these orifices ensures impact ventilation of the casing C.

On the figure 1 it can be seen that the supports S of the cooling ramps R are fixed to the casing by an upstream flange BAM and a downstream flange BAV. Although not shown, the boxes B are fixed on the housing in the same way.

In cold, that is to say when the turbines are stopped, the air gap E between an air outlet orifice formed in a tube T and the outer surface of the casing C (or "housing skin" PC) is of the order of 5 to 6 mm.

At hot, that is to say during operation of the turbines, the metal casing C tends to expand radially but especially longitudinally. However, the upstream flanges BAM and downstream BAV remain colder and do not expand in the same way as the skin of the PC casing. It follows that cooling ramps R tend to approach or even touch the skin of the PC housing in places. Although the air gap E cold is important, it is insufficient hot.

It is difficult to anticipate the expansion of the skin of the PC casing with respect to the upstream and downstream flanges. Indeed, for air jet impact cooling to be effective, the ramp must be located very close to the skin of the PC housing and therefore keep a constant air gap E. The positioning of the hot ramp is not correct, and the ramp may be either too far or too close (or even in contact) with the housing skin during operation of the turbines. It is therefore necessary to find a fixing means to maintain a constant air gap regardless of the temperature.

We already know from the document US 2014/0030066 an air jet cooling device for the wall of a gas turbine casing. This device comprises several cooling ramps mounted on an air distributor which holds them spaced apart. This air distributor is itself connected to the housing but by flanges 300, 302 fixed on the ends of the housing, so that the ramps in its middle portion may be closer to the housing in case of expansion of that -this.

PRESENTATION OF THE INVENTION

The invention therefore aims to solve the aforementioned drawbacks of the state of the art.

The invention particularly aims to provide a device for fixing air jet cooling ramps of the casing of a turbomachine turbine, which avoids the air gap variations between said ramps and the outer wall of the housing, and this, even hot, that is to say during the use of the turbine.

To this end, the invention relates to a device for fixing air jet cooling ramps of the casing of a turbine, preferably a low-pressure turbine, a turbomachine comprising a support for said ramps, shaped to maintain said ramps spaced between they and several support elements of said ramp support, each support element being fixed to said housing and connected to said ramp support by connecting means.

According to the invention, the device comprises N cooling ramps and N-1 support elements, each support element being disposed between two contiguous cooling ramps.

Thanks to these features of the invention, the gap between the ramps and the outer wall of the housing remains constant, even during hot use. Indeed, the integral support elements of the ramp support are disposed between two adjacent cooling ramps, and retain them at a constant distance from the skin of the housing. In addition, these support elements being attached to the housing, they are subject to the same temperature changes as the housing and expand according to the deformations thereof.

As the gap is kept constant, the cooling of the turbine casing is improved and the service life of the latter is increased.

• ledit support des rampes comprend deux lames dites « lame intérieure » et lame extérieure dont chacune comprend une série de gorges parallèles, séparées par une zone plane, chaque gorge étant conformée pour entourer une partie de la circonférence de l'une desdites rampes, de préférence la moitié, la lame intérieure et la lame extérieure étant assemblées de part et d'autres des rampes de refroidissement, de façon que leurs gorges respectives soient en face l'une de l'autre et entourent lesdites rampes ;
• au moins certains des moyens de liaison sont des moyens dits "fixes", qui n'autorisent pas de déplacement relatif entre ledit support de rampes et un élément de soutien ;
• au moins certains des moyens de liaison sont des moyens dits "mobiles", qui autorisent un déplacement relatif entre ledit support de rampes et un élément de soutien ;
• l'élément de soutien est percé d'un orifice circulaire, les zones planes des lames du support de rampes sont percées d'un orifice circulaire et l'élément de soutien et les deux lames sont assemblés par une vis traversant les deux orifices circulaires et coopérant avec un écrou, les orifices circulaires, la vis et l'écrou constituant lesdits moyens de liaison fixe ;
• l'élément de soutien est percé d'un orifice circulaire, les zones planes des lames du support de rampes sont percées d'un orifice oblong et l'élément de soutien et les deux lames sont assemblés par un pion épaulé traversant l'orifice circulaire et les deux orifices oblongs et coopérant avec une rondelle, l'assemblage étant fait de façon à autoriser le coulissement axial desdites lames par rapport au pion épaulé au niveau des orifices oblongs de façon à réaliser une liaison mobile ;
• l'élément de soutien est un pontet, fixé à ses deux extrémités au carter et dont la partie centrale en saillie est liée audit support de rampes.

According to other advantageous and nonlimiting features of the invention, taken alone or in combination:

• said support of the ramps comprises two blades called "inner blade" and outer blade each of which comprises a series of parallel grooves, separated by a flat area, each groove being shaped to surround part of the circumference of one of said ramps, preferably half, the inner blade and the outer blade being assembled on both sides of the cooling ramps, so that their respective grooves face each other and surround said ramps;
• at least some of the connecting means are so-called "fixed" means, which do not allow relative movement between said ramp support and a support element;
• at least some of the connecting means are so-called "mobile" means, which allow relative movement between said ramp support and a support element;
• the support element is pierced with a circular orifice, the flat areas of the blades of the ramp support are pierced with a circular orifice and the support element and the two blades are assembled by a screw passing through the two circular orifices and cooperating with a nut, the circular orifices, the screw and the nut constituting said fixed connection means;
• the support element is pierced with a circular orifice, the flat areas of the ramp support blades are pierced with an oblong orifice and the support element and the two blades are assembled by a stepped pin passing through the circular orifice. and the two orifices oblong and cooperating with a washer, the assembly being made so as to allow axial sliding of said blades relative to the stepped pin at the oblong orifices so as to achieve a movable connection;
• the support element is a bridge, fixed at both ends to the housing and whose projecting central portion is connected to said ramp support.

The invention also relates to a turbomachine which comprises a device for fixing said cooling ramps as mentioned above.

PRESENTATION OF FIGURES

Other features and advantages of the invention will appear from the description which will now be made, with reference to the accompanying drawings, which represent, by way of indication but not limitation, two possible embodiments.

• la figure 1 est une vue en perspective d'une partie d'un carter d'une turbine d'une turbomachine, équipé de rampes de refroidissement selon l'état de la technique,
• la figure 2 est une vue en perspective d'un boitier d'alimentation en air et des rampes de refroidissement selon l'état de la technique,
• les figures 3 à 6 sont des vues en perspective représentant deux modes de réalisation des différents éléments constitutifs du dispositif de fixation des rampes de refroidissement conforme à l'invention,
• la figure 7 est une vue en coupe transversale du dispositif conforme à l'invention représentant deux modes de réalisation,
• les figures 8 et 9 sont des vues de détail des zones référencées VIII et IX sur la figure 7.

On these drawings:

• the figure 1 is a perspective view of a portion of a casing of a turbomachine turbine, equipped with cooling ramps according to the state of the art,
• the figure 2 is a perspective view of an air supply box and cooling ramps according to the state of the art,
• the Figures 3 to 6 are perspective views showing two embodiments of the different elements constituting the device for fixing the cooling ramps according to the invention,
• the figure 7 is a cross-sectional view of the device according to the invention showing two embodiments,
• the Figures 8 and 9 are detailed views of the zones referenced VIII and IX on the figure 7 .

DETAILED DESCRIPTION

The device for fixing the cooling ramps according to the invention will now be described in connection with the Figures 3 to 7 .

It allows the attachment of cooling ramps 1, on the casing 2 of a turbine, preferably a low pressure turbine, a turbomachine. The cooling ramps 1 and the casing 2 have the same shapes and structures as those described previously in connection with the Figures 1 and 2 for the state of the art.

In other words, the cooling ramps 1 are formed of tubes of cross section, preferably circular and have a curved shape in a circular arc, matching the outer shape of the housing 2. The latter has a flared shape and comprises a surface 21, an upstream end 22 and a downstream end 23.

The fixing device bears the general reference 3. It comprises a support 4 of said ramps 1 and several elements 5 for supporting said support 4.

A possible embodiment of the support 4 of ramps will now be described.

This support 4 comprises two blades, respectively called inner blade 41 and outer blade 42.

As it appears better on the figure 4 , the inner blade 41 is intended to be disposed near the outer surface 21 of the housing, it comprises a series of parallel grooves 411, perpendicular to the blade and separated from each other by an intermediate flat area 412.

Each groove 411 is shaped to surround at least a portion of the circumference of one of said ramps 1. In other words, in the case where the tube of a cooling ramp is of circular section, the inner radius of the groove 411 substantially corresponds to the outer radius of a cooling ramp 1. Preferably, each groove surrounds half of the circumference of a ramp.

Similarly, the outer blade 42, intended to be disposed outside the ramps 1, also has a series of parallel grooves 421 spaced apart from each other by a flat zone 422 (see FIG. figure 1 ).

The inner blade 41 and the inner blade 42 are assembled on either side of the cooling ramps 1, so that their respective grooves 411, 412 are opposite one another and surround said ramps, as can be seen in FIG. see him on the figures 6 and 7 .

The support 4 of ramps thus makes it possible to keep the ramps 1 spaced apart from each other, in the axial direction of the casing 2.

According to a possible embodiment, the support element 5 has the shape of a bridge as can be seen on the figure 3 . Each bridge comprises two ends 51 and a projecting central portion 52.

The ends 51 are fixed to the casing 2, more precisely on the outer surface 21 thereof (also known as the "skin of the casing"), more precisely still on the portion of the outer surface 21 that extends between the upstream ends 22 and downstream 23. This fixing is carried out by any appropriate means, for example by welding, brazing, bonding, riveting or bolting.

These support elements 5 thus follow the deformation of the casing 2 due to the expansion thereof, both radially and axially.

This was not the case in the state of the art described in the document US 2014/0030066 where the air distributor supporting the cooling ramps is fixed by flanges, themselves fixed in turn at both ends of the housing so in a region where the expansion is less than in the central part of the housing.

Each support element 5 is connected to the support 4, that is to say to the two blades 41 and 42 by so-called "fixed" 6 or "mobile" connecting means 6 '.

The central portion 52 of the bridge is pierced with a circular orifice 53.

The assembly of the various elements constituting the fixing device 3 is carried out as follows.

As shown on the figure 3 , the various support elements 5 are fixed on the housing 2. The inner blade 41 is then fixed on these support elements 5, so that its planar zones 412 are positioned facing the projecting central flat part 52 of the bridge 5 (see figure 4 ).

Then, and as shown on the figure 5 the ramps 1 are arranged in the grooves 411.

Finally, as we can see on the figure 6 , the outer blade 42 is positioned on the ramps 1, so that the grooves 421 enclose the ramps 1 and that the flat areas 422 are positioned opposite the planar zones 412 of the inner blade 41.

According to the invention, and as represented for example on the figure 4 , if the cooling ramps 1 are N, then the support elements 5 according to the invention are N-1 and are arranged between the two cooling ramps 1 of each pair of ramps.

Thus, the air gap between each cooling ramp 1 and the outer surface of the casing 2 is kept constant.

At least one additional support element 5 may be further provided at at least one of the two ends of the ramp support 4.

The connecting means 6 are said to be "fixed" in that they do not allow any relative displacement between the ramp support 4 and a support element 5. This solution is represented in FIG. figure 8 and in the lower left corner of Figures 4 to 7 .

In this case, the flat areas 412, 422 of the blades 41, respectively 42, are pierced with a circular hole 413, respectively 423.

The two blades 41 and 42 and the bridge 5 are assembled by means of a screw 7 passing through said orifices 53, 413 and 423 and a nut 8 screwed onto the screw. The screw 7 being circular and the orifices 413 and 423 also and of the same diameter, there is no possibility of relative movement of the blades of the support 4 relative to the elements 5 of this support.

However, this fixed connection allows the support elements 5 to follow the radial expansion movement of the housing.

The connecting means 6 'are said to be "mobile" in that they allow relative movement between the ramp support blades 41, 42 and a support element 5. In this case, and as shown on the parts central and superior right of Figures 4 to 7 and on the figure 9 , the orifices arranged in the blades 41 and 42 are oblong and are respectively referenced 413 'and 423'.

The assembly is carried out with a stepped pin 7 'and a washer 8'. However in this case, the blades 41 and 42 can slide axially relative to the stepped pin 7 ', so that the blades 41 and 42 can follow the expansion movement of the housing 2, including its axial expansion movement.

It should be noted that, preferably, the fixed connection means 6 are used near the upstream end of the casing and the mobile connection means 6 'in the center and near the downstream end of the casing.

However, it is possible to use exclusively one or the other of said connecting means.

Claims (8)

1. A device (3) for attaching manifolds (1) for cooling by air jets the casing (2) of a turbine, preferably a low-pressure turbine, of a turbine engine, comprising a support (4) of said manifolds, shaped to hold said manifolds spaced from one another and several support elements (5) of said manifold support (4), each support element (5) being attached to said casing (2) and connected to said manifold support (4) by connecting means (6, 6'), characterized in that it comprises N cooling manifolds (1) and N-1 support elements (5), each support element (5) being disposed between two contiguous cooling manifolds.
2. The device according to claim 1, characterized in that said manifold support (4) comprises two blades so-called "interior blade" (41) and "exterior blade" (42), each one of which comprises a series of parallel grooves (411, 421), separated by a planar area (412, 422), each groove (411, 421) being shaped to surround a portion of the circumference of one of said manifolds (1), preferably half, the interior blade (41) and the exterior blade (42) being assembled on either side of the cooling manifolds (1), so that their respective grooves (411, 421) are facing one another and surround said manifolds.
3. The device according to claim 1 or 2, characterized in that at least some of the connecting means (6) are so-called "fixed" means (53, 413, 423, 7, 8), which do not allow relative movement between said manifold support (4) and a support element (5).
4. The device according to claim 1 or 2, characterized in that at least some of the connecting means (6') are so-called "moving" means (53, 413', 423', 7, 8), which allow relative movement between said manifold support (4) and a support element (5).
5. The device according to claims 2 and 3, characterized in that the support element (5) is pierced with a circular opening (53), in that the planar areas (412, 422) of the blades (41, 42) of the manifold support are pierced with a circular opening (413, 423) and in that the support element (5) and the two blades (41, 42) are assembled by a screw (7) passing through the two circular openings and cooperating with a nut (8), the circular openings, the screw and the nut constituting said fixed connecting means (6).
6. The device according to claims 2 and 4, characterized in that the support element (5) is pierced with a circular opening (53), in that the planar areas (412, 422) of the blades (41, 42) of the manifold support are pierced with an oblong opening (413', 423') and in that the support element (5) and the two blades (41, 42) are assembled by a shoulder pin (7') passing through the circular opening and the two oblong openings and cooperating with a washer (8'), the assembly being accomplished so as to allow the axial sliding of said blades (41, 42) with respect to the shoulder pin at the oblong openings so as to accomplish a moving connection (6').
7. The device according to one of the preceding claims, characterized in that the support element (5) is a saddle, attached at its two ends (51) to the casing (2) and the protruding central portion (52) whereof is connected to said manifold support (4).
8. A turbine engine comprising a turbine, particularly a low-pressure turbine, surrounded by a casing (2), equipped with cooling manifolds using air jets (1), characterized in that it comprises a device (3) for attaching said cooling manifolds (1) according to any one of said preceding claims.

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