FR3115559A1 - Turbine blade with improved cooling circuits - Google Patents

Abstract

Turbine blade with improved cooling circuits Turbine blade (114), comprising a blade body (18) extending in a main direction, an intrados wall (24), an extrados wall (26), a leading edge (20) and an edge of leak (22), the blade (114) comprising a plurality of internal cavities (31) defining a primary cooling circuit (131) of the blade (114), a secondary cooling circuit (132), comprising a plurality of internal conduits (140), each of said internal conduits (140) extending at least partially between an internal cavity (31) of the primary cooling circuit (131) and the intrados wall (24), and between the internal cavity (31) of the primary cooling circuit (131) and the extrados wall (26), so as to at least partially surround an internal cavity (31) of the primary cooling circuit (131), each of said internal conduits (140) having a lower section or equal to 2 mm. Turbomachine comprising such a blade (114). Figure for abstract: Fig. 3

Description

Turbine blade with improved cooling circuits

This presentation concerns the field of turbine blades, in particular for aircraft turbomachinery.

Increased performance needs and changes in aeronautical regulations are pushing current engine manufacturers to design engines that operate in ever more severe environments, particularly in terms of temperature, pressure, rotation speed and emission conditions. This leads to the need to define turbine blades that can withstand this type of stress.

It is known to provide a cooling circuit inside a blade to help it better withstand this type of stress, but when the cooling generated by a given cooling circuit is increased, there is a risk of generating prohibitive mechanical stresses between the relatively hot external walls of the blade and the relatively cold internal cavities inside the blade. There is therefore a need to improve cooling by limiting these constraints.

The present presentation aims to respond at least partially to these problems, and thus proposes a turbine blade, comprising a blade body extending in a main direction, an intrados wall, an extrados wall, a leading edge and a trailing edge, the blade comprising a plurality of internal cavities defining a primary cooling circuit for the blade, characterized in that it comprises a secondary cooling circuit, comprising a plurality of internal ducts, each of the said internal ducts extending at least partially between an internal cavity of the primary cooling circuit and the intrados wall, and between the internal cavity of the primary cooling circuit and the extrados wall, so as to at least partially surround an internal cavity of the primary cooling circuit, each said internal ducts having a section less than or equal to 2mm².

Such a blade makes it possible to distribute the temperature difference between the outside and the inside of the blade body over two cooling circuits, reducing the mechanical stresses to which the blade body is subjected.

According to one example, the primary cooling circuit comprises two internal cavities arranged successively along a thickness of the blade body, the thickness at a point of the blade body being the minimum distance between its intrados wall and its extrados wall, and in which all or part of the internal ducts of the secondary cooling circuit extending between said two internal cavities are arranged successively according to the thickness of the blade body.

According to one example, the plurality of internal cavities comprises a first internal cavity and a second internal cavity, the first internal cavity and the second internal cavity arranged successively according to a thickness of the blade body, the thickness at a point of the blade being the minimum distance between its intrados wall and its extrados wall, and in which the secondary cooling circuit comprises a first plurality of internal ducts and a second plurality of internal ducts, each internal duct of the first plurality of internal ducts comprising a section s extending between the first internal cavity and the second internal cavity, each internal duct of the second plurality of internal ducts being connected to said section, and diverging from said internal duct of the first plurality of internal ducts to at least partially surround the second internal cavity and to emerge in said section.

According to one example, the primary cooling circuit comprises two internal cavities arranged successively between the leading edge and the trailing edge, and in which all or part of the internal ducts of the secondary cooling circuit extending between said two internal cavities are arranged successively between the leading edge and the trailing edge.

According to one example, the plurality of internal ducts surround a first internal cavity of the plurality of internal cavities, and each comprise a first section, extending towards the first internal cavity from a second internal cavity of the plurality of internal cavities, and a second section, extending towards the second internal cavity from the first internal cavity, the first section and the second section each extending between the first internal cavity and the second internal cavity, the first section and the second section are arranged successively in the main direction.

According to one example, all or part of the internal ducts of the secondary cooling circuit have a component along the main direction of the blade which evolves as they travel around the internal cavities.

According to one example, all or part of the internal ducts opens onto the intrados wall or onto the extrados wall of the blade body.

According to one example, all or part of the internal ducts are connected to the internal cavities of the primary cooling circuit.

According to one example, all or part of the internal ducts have a converging section in one direction of fluid flow.

This presentation also relates to a turbomachine comprising a blade as described above.

This presentation also relates to an aircraft comprising such a turbomachine.

This disclosure may be better understood by considering the following detailed description of aspects of the disclosure in light of the figures, in which:

there shows an example of an aircraft comprising a turbomachine;

there shows an example of a turbine blade;

there shows an example of a core of part of a blade cooling circuit;

there shows a schematic sectional view of part of a blade body of a blade, according to a first variant;

there represents a three-dimensional schematic view of an example of the cores of the cooling circuits visible in ;

there shows a schematic sectional view of a blade body part of a blade, according to a second variant;

there shows a schematic sectional view of a blade body part of a blade, according to a third variant;

there shows a schematic sectional view of a blade body part of a blade, according to a fourth variant;

there represents a schematic sectional view of a blade body part of a blade, according to a fifth variant.

Other characteristics and advantages of the object of this presentation will emerge from the following description of embodiments, given by way of non-limiting examples, with reference to the appended figures.

We see, in , an example of an aircraft 10, in this case an airplane, comprising a turbomachine 12. In known manner, the turbomachine 12 comprises one or more turbines each having several blades.

There represents an example of a turbine blade 14, for example for the turbine engine 12 visible in . In known manner, the blade 14 extends in a main direction, typically corresponding to a radial direction for the turbomachine 12. The blade 14 successively comprises in said main direction, from an internal radius to an external radius, a root of blade 16, making it possible to mount the blade 14 in the turbine engine, a blade body 18 extending radially towards the outside of the turbine engine from the blade root 16, and a blade tip forming the end outer radial of the blade 14.

In known manner, the blade body 18 comprises a leading edge 20, a trailing edge 22, an underside wall 24 extending between the trailing edge 22 and the leading edge 20, and an extrados wall 26 extending between the leading edge 20 and the trailing edge 22, on the opposite side of the intrados wall 24, so that the leading edges 20 and the trailing edge 22 are connected to one another the other by the intrados wall 24 and the extrados wall 26.

In known manner, when the blade 14 is mounted in the turbomachine 12, the leading edge 20 is arranged towards a combustion chamber of the turbomachine 12, relative to the trailing edge 22, the intrados wall 24 is arranged towards the combustion chamber, and the extrados wall 26 is arranged on the other side of the leading edge 20, and is oriented away from the combustion chamber. The leading edge 20 and the trailing edge 22, and the intrados wall 24 and the extrados wall 26 form an outer wall of the blade body 18. In the direction of the gas flow in the turbomachine 12, the edge of the attack 20 is located upstream, and the trailing edge 22 is located downstream, relative to the rest of the blade body 18.

The blade 14 comprises a cooling circuit 30 allowing cooling fluid to flow (for example air taken from a compressor of the turbomachine 12) into the blade body 18. For example, the cooling fluid can penetrate into the blade body 18 via inlets formed in the blade root 16. The cooling fluid entering the blade 14 can exit the blade body 18 via bores 40 formed in the leading edge 20 and/or the trailing edge 22 and/or the intrados wall 24 and/or the extrados wall 26 to generate a cooling film effect on the surface of the blade 14, commonly referred to as "film cooling". », or cooling effect by cooling layer of fluid.

There shows an example of a core 39 of a known blade cooling circuit, for example the cooling circuit 30 the blade 14 shown in . Such a core 39 has a shape complementary to the shape of a cooling circuit formed with this core 39, and thus makes it possible to visualize an example of geometry of the corresponding cooling circuit. A cooling circuit is typically formed by lost-wax casting, using a core 39 to define recesses in the blade body (between the leading edge and the trailing edge, and between the lower surface and the extrados wall). Thus, it can be seen that the corresponding cooling circuit comprises several internal cavities, defined by the bodies 31', 32', 33', 34', 35' of the core 39 extending parallel to the leading edge and/or to the edge vane body leakage. For simplicity, the holes 40 are not shown. The internal cavities defined by the bodies 31', 32', 33', 34', 35' of the core 39 of the cooling circuit can be connected to each other and/or to the holes 40 in the intrados wall or in the extrados wall.

Core 39 is typically made of ceramic or any other material suitable for investment casting.

There represents a schematic cross-sectional view of part of a blade body 18 of a turbine engine blade 114 (for example the turbine engine 12 visible in ) according to a first variant of this presentation. The section is taken perpendicular to the main direction in which the blade body 18 extends. In this case, the main direction is the radial direction of a turbine or turbomachine comprising the blade 114.

The blade 114 includes a primary cooling circuit 131 defined by a plurality of internal cavities, of which we see a first internal cavity 31 here.

The first internal cavity 31 is arranged between the intrados wall 24 and the extrados wall 26 of the blade body 18 and extends in the main direction. The thickness of the first internal cavity 31, measured in a direction normal to the intrados wall 24, is of the order of 1 cm (centimeter) or less, for example, depending on the size of the blade 114 and/or the complexity of its cooling circuit(s).

The blade 114 also comprises a secondary cooling circuit 132 comprising a first plurality of internal ducts 140. Each of the internal ducts 140 of the first plurality of internal ducts 140 extends at least partially between the first internal cavity 31 and the intrados wall 24, and also between the first internal cavity 31 and the extrados wall 26, so as to at least partially surround the first internal cavity 31 in a projection view along a plane perpendicular to the main direction of the blade 114.

Each of the internal ducts 140 of the first plurality of internal ducts 140 comprises a first part 141 which runs along the intrados wall 24. By "along", is meant for example that a wall 141P of the first part 141 of the internal duct 140 of the first plurality of internal ducts 140 is locally parallel to a surface tangent to the intrados wall 24, while being separate from the intrados wall 24. Thanks to the cooling fluid flowing in the first part 141 of each of these internal ducts 140, it is possible to cool the intrados wall 24 by convection. The heat recovered by the cooling fluid can then be transferred by convection to the blade body 18, and then transferred by conduction through the blade body 18 to the first internal cavity 31.

Each of the internal ducts 140 of the first plurality of internal ducts 140 comprises a second part 142 which is arranged between the first internal cavity 31 and the extrados wall 26. In this case, the second parts 142 of the internal ducts 140 of the first plurality of internal ducts 140 run along the extrados wall 26, which means for example that a wall 142P of each second part 142 of the internal ducts 140 of the first plurality of internal ducts 140 is locally parallel to a surface tangent to the extrados wall 26 , while being separate from the extrados wall 26. Thanks to the cooling fluid flowing in the second part 142 each of these internal ducts 140, it is possible to cool the extrados wall 26 by convection. The heat recovered by the cooling fluid can be transferred to the first internal cavity 31 in the same manner described previously.

Each of the internal ducts 140 of the first plurality of internal ducts 140 comprises a third part 143 which connects its first part 141 and its second part 142 to each other. The third part 143 of each of these internal ducts 140 makes it possible to transfer cooling fluid from the intrados wall 24 to the intrados wall 26. In this case, the third part 143 of each internal duct 140 of the first plurality of internal ducts 140 allows cooling fluid to be transferred to the intrados wall 24.

During its passage through the third part 143 of a given internal conduit 140 of the first plurality of internal conduits 140, the cooling fluid is cooled by convection with the blade body 18. The blade body 18 conducts heat recovered from the cooling fluid in the internal conduits 140 of the first plurality of internal conduits 140 towards the first internal cavity 31.

Each of the internal ducts 140 of the first plurality of internal ducts 140 may also comprise a fourth part 144 extending from the second part 142 towards the intrados wall 24. The fourth part 144 and the third part 143 of a given internal duct 140 of the first plurality of internal ducts 140 are arranged on opposite sides of the first internal cavity 31. Thus, each internal duct 140 of the first plurality of internal ducts 140 can completely surround the first internal cavity 31 in a projection view according to a perpendicular plane to the main directorate. In this case, the third parts 143 of the internal ducts 140 of the first plurality of internal ducts 140 are arranged between the first internal cavity 31 and the leading edge of the blade 114, and the fourth parts 144 of the internal ducts 140 of the first plurality of internal ducts 140 are arranged between the first internal cavity 31 and the trailing edge of the blade 144. By way of example, the fourth part 144 of a given internal duct 140 of the first plurality of ducts internal ducts 140 can be connected to another part of the given internal duct 140 of the first plurality of internal ducts 140 which runs along the intrados wall 24, or which opens into a bore in the intrados wall 24.

All or part of each of the internal ducts 140 of the first plurality of internal ducts 140 extends in one or more directions, a component of which along the main direction evolves as they extend around the first internal cavity 31. For example , projections of the first part 141, the second part 142, and the third part 143 of a given internal duct 140 of the first plurality of internal ducts 140 (and in this case the fourth part 144 of the given internal duct 140 of the first plurality of internal ducts 140 also) on a plane perpendicular to the main direction extend circumferentially around the first internal cavity 31, the first part 141, the second part 142, the third part 143, and if necessary the fourth part 144 of the given internal duct 140 of the first plurality of internal ducts 140 also extend along the main direction. We speak of a helical arrangement of the given internal duct 140 of the first plurality of internal ducts 140 with respect to the first internal cavity 31. However, the term “helical” is not necessarily limited to a round shape of the projection according to a plane perpendicular to the main direction. Thus, it is understood that although the internal duct 140 has been represented in the same plane on the , this figure is actually a projection of the internal duct 140 in a given section plane, and that the internal duct 140 actually typically has a helical shape as indicated above.

Each of the internal ducts 140 of the first plurality of internal ducts 140 has a maximum section equal to or less than 2 mm² (square millimeter). The section of each internal duct 140 of the first plurality of internal ducts 140 can converge in the direction of flow, in order to limit pressure drops.

The first part 141 of each internal duct 140 can be oriented so as to convey cooling fluid away from the blade root. In addition or alternatively, the second part 142 of each internal duct 140 can be oriented so as to convey cooling fluid to the blade root.

There represents an example of a first core 138 and an example of a second core 139, representing respectively at least a part of the primary cooling circuit 131 and at least a part of the secondary cooling circuit 132 visible in . The secondary cooling circuit 132 may comprise several internal ducts 140 arranged around the same internal cavity 31. For example, here in we see four bodies 139a, 139b, 139c, 139d of the second core 139, defining four internal ducts 140 of the secondary cooling circuit 132, successively interposed in the main direction around a given body of the first core 138. Each of the four body 139a, 139b, 139c, 139d of the second core 139 is arranged helically around the body of the first core 138, thus defining the internal ducts 140 of the secondary cooling circuit 132 which are arranged helically around the internal cavity 31 of the primary cooling circuit 131.

The various internal ducts 140 of the secondary cooling circuit 132 can take cooling fluid, for example from the internal cavities 31 of the primary cooling circuit 131, or from a stream of fluid in which the blade 114 is installed.

The internal ducts 140 of the secondary cooling circuit 132 discharge cooling fluid typically into an internal cavity 31 of the primary cooling circuit 131, and/or onto the intrados wall and/or onto the extrados wall via holes opening onto said walls. Thus rejecting the cooling fluid on the extrados wall and/or the intrados wall makes it possible in particular to form a film of cooling fluid on the surface of the blade 114.

The helical arrangement of a given internal conduit 140 allows the cooling fluid to circulate therein so as to move away from the root of the blade, in particular due to the Coriolis effect during the rotation of the turbine comprising the blade 114 .

Alternatively, a given internal duct 140 can be oriented so as to convey cooling fluid towards the blade root by housing the extrados wall 26, and so as to convey cooling fluid away from the blade root along the intrados wall 24 in order to improve heat exchange with the external walls by benefiting from the Coriolis effect.

The set of cooling circuits 131, 132 can be formed by manufacturing the core 138 corresponding to the primary cooling circuit 131, and the core 139 corresponding to the secondary cooling circuit 132, and by assembling the core 138 corresponding to the primary cooling circuit 131 and the core 139 corresponding to the secondary cooling circuit 132. The core 138 corresponding to the primary cooling circuit 131 can be manufactured by injection of the ceramic material described above, or by deposition in the context of additive manufacturing, or by any known manner for making cores. The core 139 corresponding to the secondary cooling circuit 132 can be made of refractory metal, for example. The core 138 corresponding to the primary cooling circuit 131 and the core 139 corresponding to the secondary cooling circuit 132 are then assembled, for example mechanically, by bonding, by over-injection of the ceramic on the RMC (the secondary cooling circuit in RMC is d first manufactured by integrating overlengths towards the primary circuit then placed in the injection mold of the ceramic part: during the injection of the ceramic, the overlengths will be taken in the ceramic, which will ensure assembly), or by juxtaposition in a lost-wax foundry mould.

There represents a schematic cross-sectional view of part of a blade body 18 of a blade 214 according to a second variant of this presentation. The second variant will be described in terms of its differences from the first variant. The section is taken perpendicular to the main direction.

The primary cooling circuit 131 comprises a second internal cavity 32 formed in the blade body 18. The first internal cavity 31 and the second internal cavity 32 are arranged successively along a thickness of the blade body 18, and are separated one from the other by an internal partition 220. The thickness of the blade body 18 is the minimum distance, at a given point of the blade body 18, between the intrados wall 24 and the extrados wall 26 of the blade body. blade 18. By way of example, the internal partition 220 can have a thickness, measured between the first internal cavity 31 and the second internal cavity 32, of 1 mm or less.

The first internal cavity 31 and the second internal cavity 32 can be connected to each other, or isolated from each other.

All or part of the internal ducts 140 of the first plurality of internal ducts 140 extend between the first internal cavity 31 and the second internal cavity 32. In the example illustrated, the second parts 142 of the internal ducts 140 of the first plurality of internal ducts 140 extend between the first internal cavity 31 and the second internal cavity 32 so that the first internal cavity 31, the second part 142 of a given internal duct 140 of the first plurality of internal ducts 140 and the second internal cavity 32 are arranged successively according to the thickness of the blade body 18. The second parts 142 of the internal ducts 140 of the first plurality of internal ducts 140 are formed in the internal partition 220.

The secondary cooling circuit 132 comprises a second plurality of internal cavities 160, which extend at least partially between the second internal cavity 32 and the intrados wall 24, and between the second internal cavity 32 and the extrados wall 26, so as to at least partially surround the second internal cavity 32.

Each internal duct 160 of the second plurality of internal ducts 160 comprises a first part 161 disposed between the second internal cavity 32 and the intrados wall 24. In this case, the first parts 161 of the internal ducts 160 of the second plurality of internal ducts 160 extend between the first internal cavity 31 and the second internal cavity 32. The first parts 161 of the internal ducts 160 of the second plurality of internal ducts 160 are formed in the internal partition 220. The first part 161 of an internal duct 160 given of the second plurality of internal ducts 160 and the second part 142 of an internal duct 140 of the first plurality of internal ducts 140 are arranged successively along the thickness of the blade body 18, and are separate.

Each internal duct 160 of the second plurality of internal ducts 160 comprises a second part 162 running along the extrados wall 26, which means that a wall 162P of the second part 162 of each internal duct 160 of the second plurality of internal ducts 160 is locally parallel to a surface tangent to the extrados wall 26, and separate from the extrados wall 26. Thanks to the convection of the cooling fluid flowing therein, the second part 162 of the internal pipe 160 of the second plurality of internal pipes 160 makes it possible to cool the extrados wall 26. The heat recovered by the cooling fluid can then be transferred by convection to the blade body 18, and then transferred by conduction through the blade body 18 to the second internal cavity 32.

Each internal duct 160 of the second plurality of internal ducts 160 comprises a third part 163 connecting its first part 161 and its second part 162 to each other. The third part 163 of each of the internal ducts 160 of the second plurality of internal ducts 160 makes it possible to transfer cooling fluid from the internal partition 220 to the extrados wall 26. The third part 143 of each internal duct 140 of the first plurality of ducts internal 140 conveys fluid from the intrados wall 24 to the internal partition 220.

Each of the internal ducts 160 of the second plurality of internal ducts 160 may also comprise a fourth part 164 extending from its second part 161 towards the extrados wall 26 – in this case towards the internal partition 220. The third parts 163 and the fourth portions 164 of the internal ducts 160 of the second plurality of internal ducts 160 are arranged on opposite sides of the second internal cavity 32. Thus, each internal duct 160 of the first plurality of internal ducts 160 can completely surround the second internal cavity 32 in a projection of the internal duct 160 of the first plurality of internal ducts 160 on a plane perpendicular to the main direction.

All or part of each of the internal ducts 160 of the second plurality of internal ducts 160 extends in one or more directions, a component of which along the main direction evolves as they extend around the second internal cavity 32. For example , projections of the first part 161, the second part 162, and the third part 163 of a given internal duct 160 of the second plurality of internal ducts 160 (and in this case its fourth part 164 as well) on a perpendicular plane in the main direction extend circumferentially around the second internal cavity 32, and the first part 161, the second part 162, the third part 163 and if necessary the fourth part 164 of the given internal duct 160 of the second plurality of ducts internal 160 also extend along the main direction. Thus, it is understood that although the internal ducts 140, 160 have been represented in the same plane on the , this figure is actually a projection of the internal ducts 140, 160 in a given section plane, and that each of the internal ducts 140, 160 actually typically has a helical shape as indicated above.

The second part 162 of each internal duct 160 of the second plurality of internal ducts 160 can be oriented so as to convey cooling fluid to the blade root.

The first part 161 of each internal duct 160 of the second plurality of internal ducts 160 can be oriented so as to convey cooling fluid away from the blade root. The first parts 161 of the internal ducts 160 of the second plurality of internal ducts 160 run along the second parts 142 of the internal ducts 140 of the first plurality of internal ducts 140. It is therefore understood that a wall 161P of the first part 161 of a given internal duct 160 of the second plurality of internal ducts 160 is locally parallel to a surface tangent to a wall 142P of the second part 142 of a given internal duct 140 of the first plurality of internal ducts 140, while being separate from this wall 142P of the second part 142 of the given internal duct 140 of the first plurality of internal ducts 140. Along the second parts 142 of the internal ducts 140 of the first plurality of internal ducts 140, the first parts 161 of the internal ducts 160 of second plurality of internal ducts 160 and the second portions 142 of the internal ducts 140 of the first plurality of internal ducts 140 nt a cross-flow heat exchanger function between the first internal cavity 31 and the second internal cavity 32.

There represents a schematic cross-sectional view of part of a blade body 18 of a blade 314 according to a third variant of this description. The section view is taken as described for the . The third variant will be described in terms of its differences from the second variant.

The first internal cavity 31 and the second internal cavity 32 are formed in the blade body 18 so as to be arranged successively between the leading edge and the trailing edge of the blade 314.

As we saw in , the second part 142 of each internal duct 140 of the first plurality of internal ducts 140 runs along the extrados wall 26. The fourth part 144 of each internal duct 140 of the first plurality of internal ducts 140 is formed in the internal partition 220 and conveys cooling fluid to the extrados wall 26.

The first part 161 of each internal duct 160 of the second plurality of internal ducts 160 runs along the intrados wall 24, and is therefore separated from the intrados wall 24. The third part 163 of each internal duct 160 of the second plurality of internal ducts 160 is formed in the internal partition 220 and conveys cooling fluid to the extrados wall 26. The fourth part 164 of each internal duct 160 of the second plurality of internal ducts 160 conveys cooling fluid to the intrados wall 24. By way of example , the fourth part 164 of a given internal duct 160 of the second plurality of internal ducts 160 can be connected to another part of the given internal duct 160 of the second plurality of internal ducts 160 which runs along the intrados wall 24, or which opens in a hole in the intrados wall 24.

The third parts 163 of the internal ducts 160 of the second plurality of internal ducts 160 run along the fourth parts 144 of the internal ducts 140 of the first plurality of internal ducts 140. It is therefore understood that a wall 163P of a third part 163 of a given internal duct 160 of the second plurality of internal ducts 160 is locally parallel to a surface tangent to a wall 144P of a fourth part 144 of a given internal duct 140 of the first plurality of internal ducts 140, while being disjoint of this wall 144P of the fourth part 144 of the given internal duct 140 of the first plurality of internal ducts 144, and extend between the first internal cavity 31 and the second internal cavity 32. By way of example, the third parts 163 internal ducts 160 of the second plurality of internal ducts 160 can be oriented parallel to the fourth portions 144 of the internal ducts 140 of the first plurality of e internal ducts 140, so as to perform a counter-current heat exchanger function between the first internal cavity 31 and the second internal cavity 32.

In this case, the third parts 163 of the internal ducts 160 of the second plurality of internal ducts 160 and the fourth parts 144 of the internal ducts 140 of the first plurality of internal ducts 140 are arranged between the leading edge and the edge of the blade leak 314. However, it is also envisaged to arrange the third part 163 of a given internal duct 160 of the second plurality of internal ducts 160 and the fourth part 144 of a given internal duct 140 of the first plurality internal ducts 140 successively in the main direction.

There represents a schematic view of a section of a part of a blade body 18 of a blade 414 according to a fourth variant of this description. The section view is similar to that already described with reference to the . The fourth variant will be described in terms of its differences from the first variant.

The primary cooling circuit 131 is identical to that visible in , with an internal partition 220 separating the first internal cavity 31 and the second internal cavity 32.

Each internal duct 140 of the first plurality of internal ducts 140 (of the secondary cooling circuit 132) comprises a first section 140A extending towards the second internal cavity 32 from the first internal cavity 31, extending between the first internal cavity 31 and the second internal cavity 32, and a second section 140B extending towards the first internal cavity 31 from the second internal cavity 32, extending between the first internal cavity 31 and the second internal cavity 32. The first section 140A allows the cooling fluid to be routed towards the intrados wall 24 and towards the trailing edge of the blade 414, passing between the first internal cavity 31 and the second internal cavity 32; the second section 140B makes it possible to convey cooling fluid towards the intrados wall 24 and towards the leading edge of the blade 414, passing between the first internal cavities 31 and the second internal cavity 32. In this case, the first section 140A is connected to second part 142 of internal duct 140 of the first plurality of internal ducts 140, and conveys cooling fluid from the latter to between second internal cavity 32 and intrados wall 24; the second section 140B is connected to the first part 141 of the internal duct 140 of the first plurality of internal ducts 140, and conveys cooling fluid to the latter from between the second internal cavity 32 towards the extrados wall 26.

The first internal cavity 31, the fourth part 144 of each internal duct 140 of the first plurality of internal ducts 140, and the second internal cavity 32 are arranged successively between the leading edge and the trailing edge of the blade 414. The fourth part 144 of the internal duct 140 of the first plurality of internal ducts 140 is part of the first section 140A of the internal duct 140 of the first plurality of internal ducts 140. The fourth part 144 of the internal duct 140 of the first plurality of internal ducts 140 is formed in the internal partition 220. In this case, the fourth part 144 of the internal duct 140 of the first plurality of internal ducts 140 is oriented so as to convey cooling fluid towards the trailing edge and towards the intrados wall 24 passing between the first internal cavity 31 and the second internal cavity 32.

Each first section 140A of a given internal duct 140 of the first plurality of internal ducts 140 also comprises a fifth part 145 of the given internal duct 140 of the first plurality of internal ducts 140, which is placed between the second internal cavity 32 and the intrados wall 24, and which is connected to the fourth part 144 of the given internal duct 140 of the first plurality of internal ducts 140. The fifth part 145 of the given internal duct 140 of the first plurality of internal ducts 140 makes it possible to transfer heat from the intrados wall 24 towards the second internal cavity 32. In the example illustrated, the fifth part 145 of each internal duct 140 of the first plurality of internal ducts 140 runs along the intrados wall 24. It is therefore understood that a wall 145P of the fifth part 145 of a given internal duct 140 of the first plurality of internal ducts 140 is locally parallel to a surface tangent to the inner wall bone 24, while being separate from the intrados wall 24.

The second section 140B of a given internal duct 140 of the first plurality of internal ducts 140 comprises a sixth part 146 of the given internal duct 140 of the first plurality of internal ducts 140, which is placed between the second internal cavity 32 and the wall extrados 26. The sixth part 146 of the given internal duct 140 of the first plurality of internal ducts 140 makes it possible to transfer heat from the extrados wall 26 to the second internal cavity 32. In the example illustrated, the sixth part 146 of the duct internal duct 140 given of the first plurality of internal ducts 140 runs along the extrados wall 26. It is therefore understood that a wall 146P of the sixth part 146 of the internal duct 140 given of the first plurality of internal ducts 140 is locally parallel to a tangent surface to the extrados wall 26, while being separate from the extrados wall 26.

The second section 140B of a given internal duct 140 of the first plurality of internal ducts 140 also comprises a seventh part 147 of the given internal duct 140 of the first plurality of internal ducts 140, which is placed between the first internal cavity 31 and the second internal cavity 32, and which is connected to the sixth part 146 of the given internal duct 140 of the first plurality of internal ducts 140. The seventh part 147 of the given internal duct 140 of the first plurality of internal ducts 140 is formed in the partition internal cavity 220. The first internal cavity 31, the seventh part 147 of the given internal duct 140 of the first plurality of internal ducts 140, and the second internal cavity 32 are arranged successively between the leading edge and the trailing edge of the blade 414. The seventh part 147 of the given internal duct 140 of the first plurality of internal ducts 140 connects the sixth part 146 of the given internal duct 140 of the a first plurality of internal ducts 140 to the first part 141 of the given internal duct 140 of the first plurality of internal ducts 140, and makes it possible to convey cooling fluid to the intrados wall 24 by passing between the first internal cavity 31 and the second cavity internal duct 32. In the example illustrated, said seventh part 147 of the given internal duct 140 of the first plurality of internal ducts 140 is oriented so as to convey cooling fluid towards the leading edge and the intrados wall 24 passing between the first internal cavity 31 and the second internal cavity 32.

The first section 140A and the second section 140B of each internal duct 140 of the first plurality of internal ducts 140 remain separate between the first internal cavity 31 and the second internal cavity 32; they thus intersect at different heights according to the main direction. In this case, the fourth part 144 of a given internal duct 140 of the first plurality of internal ducts 140 is arranged above the seventh part 147 of the given internal duct 140 of the first plurality of internal ducts 140, and a wall 147P of the seventh part 147 of the given internal duct 140 of the first plurality of internal ducts 140 is separated from the fourth part 144 of the given internal duct 140 of the first plurality of internal ducts 140 by a distance of 0.6 mm, for example .

For simplicity, only one inner conduit 140 of the first plurality of inner conduits 140 is shown. To clearly distinguish between the first section 140A and the second section 140B, the first section 140A is shown in solid lines and the second section 140B is shown in dotted lines. It is understood that the inner duct 140 illustrated may include still other parts. For example, its sixth part 146 can receive cooling fluid from a part of the secondary cooling circuit 132 which is located behind the plane of section, and/or its fifth part 145 can open out into a part of the secondary cooling circuit 132 which is is in front of the section plane. Furthermore, it is envisaged that its fifth part 145 opens into a section which makes it possible to convey cooling fluid according to the thickness of the blade body 18, in the direction of the extrados wall 26, or into a section opening into holes in the extrados wall 26 or the intrados wall 24 of the blade 414.

There represents a schematic view of a section of a part of a blade body 18 of a blade 514 according to a fifth variant of the present description. The section view is similar to that already described with reference to the . The fifth variant will be described in terms of its differences from the first variant.

The primary cooling circuit 131 is identical to that of the , with an internal partition 220 separating the first internal cavity 31 and the second internal cavity 32.

The secondary cooling circuit 132 includes a first plurality of internal conduits 140, as well as a second plurality of internal conduits 160. The first plurality of internal conduits 140 will be described in terms of its differences from the first plurality of internal conduits shown in connection with the .

The internal ducts 160 of the second plurality of internal ducts 160 at least partially surround the second internal cavity 32. Each internal duct 160 of the second plurality of internal ducts 160 is connected to the second part 142 of a corresponding internal duct 140 of the first plurality of internal ducts 140, so that the second part 142 of a given internal duct 140 of the first plurality of internal ducts 140 forms a section common to the internal duct 160 of the second plurality of internal ducts 160 and to the internal duct 140 corresponding to the first plurality of internal ducts 140, extending between the first internal cavity 31 and the second internal cavity 32. The common section can be oriented so as to convey fluid towards the blade root, for example by passing between the first internal cavity 31 and the second internal cavity 32. The common section is formed in the internal partition 220.

Each internal duct 160 of the second plurality of internal ducts 160 comprises a first part 161 which is connected to the common section and which diverges from the fourth part 144 of the corresponding internal duct 140 of the first plurality of internal ducts 140. The first part 161 of the internal duct 160 of the second plurality of internal ducts 160 makes it possible to convey cooling fluid from the common section to the extrados wall 26. In this case, the first part 161 of the internal duct 160 of the second plurality of internal ducts 160 is connected to a second part 162 of the internal duct 160 of the second plurality of internal ducts 160, which runs along the extrados wall 26, in the same manner described in connection with the . The second part 162 of the internal duct 160 of the second plurality of internal ducts 160 can be oriented so as to route fluid away from the blade root, for example. However, it is also envisaged that the first part 161 of the internal duct 160 of the second plurality of internal ducts 160 is connected to a part of the internal duct 160 of the second plurality of internal ducts 160 which opens into a bore in the extrados wall 26 .

The second part 162 of the internal duct 160 of the second plurality of internal ducts 160 is connected to a third part 163 of the internal duct 160 of the second plurality of internal ducts 160, which is connected to the common section, and which opens into the common section , converging with the third part 143 of the internal duct 140 corresponding to the first plurality of internal ducts 140. The third part 163 of the internal duct 160 of the second plurality of internal ducts 160 thus makes it possible to convey cooling fluid to the internal partition 220. The third part 163 and the first part 161 of the internal duct 160 of the second plurality of internal ducts 160 are arranged on opposite sides of the second internal cavity 32.

In any of the examples presented above, it is envisaged that at least one of the internal ducts of the secondary cooling circuit 132 be configured to take cooling fluid from the primary cooling circuit 131. For example, one at least one of the internal ducts 140 of the first plurality of internal ducts 140 can be configured to draw cooling fluid from the first internal cavity 31, and/or if necessary from the second internal cavity 32. In addition or alternatively, one at least one of the internal conduits 160 of the second plurality of internal conduits 160 may be configured to draw fluid from at least one of the first internal cavity 31 and the second internal cavity 32. However, it is also contemplated that fluid cooling either injected directly into the secondary cooling circuit 132, instead of being taken from the first internal cavity 31, and/or if necessary the second th internal cavity 32 of the primary cooling circuit 131.

In any of the examples presented above, it is envisaged that the secondary cooling circuit 132 is configured to lead to at least one of the intrados wall 24 and the extrados wall 26 and the leading edge and the trailing edge, in order to form a film of fluid on the intrados wall 24 and/or the extrados wall 26 of the blade 114, 214, 314, 414, 514. However, it is also envisaged that the secondary cooling circuit 132 opens into the primary cooling circuit 131, for example into the first internal cavity 31, and/or where applicable the second internal cavity 32 of the primary cooling circuit 131.

Although the present description refers to specific embodiments, modifications can be made to these examples without departing from the general scope of the invention as defined by the claims. Furthermore, individual features of the different illustrated or mentioned embodiments can be combined in additional embodiments. Accordingly, the description and the drawings should be considered in an illustrative rather than restrictive sense.

Claims (10)

Turbine blade (114, 214, 314, 414, 514), comprising a blade body (18) extending in a main direction, an intrados wall (24), an extrados wall (26), an edge of attack (20) and a trailing edge (22), the blade (114, 214, 314, 414, 514) comprising a plurality of internal cavities (31) defining a primary cooling circuit (131) of the blade ( 114, 214, 314, 414, 514), characterized in that it comprises a secondary cooling circuit (132), comprising a plurality of internal ducts (140), each of said internal ducts (140) extending at least partially between an internal cavity (31) of the primary cooling circuit (131) and the intrados wall (24), and between the internal cavity (31) of the primary cooling circuit (131) and the extrados wall (26), so as to at least partially surround an internal cavity (31) of the primary cooling circuit (131), each of said internal ducts (140) having a lower section or equal to 2 mm². Blade (214) according to Claim 1, in which the primary cooling circuit (131) comprises two internal cavities (31, 32) arranged successively along a thickness of the blade body (18), the thickness at a point of the body blade (18) being the minimum distance between its intrados wall (24) and its extrados wall (26), and in which all or part of the internal ducts (140, 160) of the secondary cooling circuit (132) extending between said two internal cavities (31, 32) are arranged successively according to the thickness of the blade body (18). A blade (514) according to any of claims 1-2, wherein the plurality of internal cavities (31, 32) comprises a first internal cavity (31) and a second internal cavity (32), the first internal cavity (31 ) and the second internal cavity (32) arranged successively along a thickness of the blade body (18), the thickness at a point of the blade (514) being the minimum distance between its lower surface wall (24) and its wall upper surface (26), and wherein the secondary cooling circuit (132) includes a first plurality of internal ducts (140) and a second plurality of internal ducts (160), each internal duct of the first plurality of internal ducts (140) comprising a section (142) extending between the first internal cavity (31) and the second internal cavity (32), each internal conduit of the second plurality of internal conduits (160) being connected to said section (142), and diverging from said internal conduit of the first plurality of internal conduits rnes (140) to at least partially surround the second internal cavity (32) and to open into said section (142). Blade (314) according to any one of claims 1-3, in which the primary cooling circuit (131) comprises two internal cavities (31, 32) arranged successively between the leading edge (20) and the trailing edge (22), and in which all or part of the internal ducts (140, 160) of the secondary cooling circuit (132) extending between the said two internal cavities (31, 32) are arranged successively between the leading edge (20 ) and the trailing edge (22). A blade (414) according to any of claims 1-4, wherein the plurality of internal ducts (140) surround a first internal cavity (31) of the plurality of internal cavities (31, 32), and each include a first section, extending to the first internal cavity (31) from a second internal cavity (32) of the plurality of internal cavities (31, 32), and a second section, extending to the second internal cavity (32) from the first internal cavity (31), the first section and the second section each extending between the first internal cavity (31) and the second internal cavity (32), the first section and the second section are arranged successively in the main direction . Vane (114, 214, 314, 414, 514) according to any one of claims 1-5, in which all or part of the internal ducts (140) of the secondary cooling circuit (132) have a component along the main direction of the blade (114, 214, 314, 414, 514) which evolves as they travel around the internal cavities (31). Blade (114, 214, 314, 414, 514) according to any one of Claims 1-6, in which all or part of the internal ducts (140) open onto the intrados wall (24) or onto the extrados wall (26) of the blade body (18). Blade (114, 214, 314, 414, 514) according to any one of claims 1-7, in which all or part of the internal ducts (140) are connected to the internal cavities (31) of the primary cooling circuit (131) . Blade according to any one of Claims 1-8, in which all or part of the internal ducts have a converging section in one direction of fluid flow. A turbomachine (12) comprising a vane (114, 214, 314, 414, 514) according to any one of claims 1-9.