This application is a National Stage of International Application No. PCT/FR2020/050524 filed Mar. 12, 2020, claiming priority based on French Patent Application No. 1902662 filed Mar. 15, 2019, the entire contents of each of which being herein incorporated by reference in their entireties.
The field of the invention relates to multiple flow turbomachines, and more precisely the flow straighteners of a turbomachine with multiple separate flows.
A multiple flow turbomachine as illustrated in
The casing 3 houses the compression, combustion and expansion elements of the turbomachine.
The fan shroud 2 extends radially outside the fan 1 and the casing 3 so as to delimit the flow entering the fan 1.
The fan 1 compresses and accelerates the flow of air entering the fan shroud 2, this flow of air then circulating in a primary circuit 4 and a secondary circuit 5, the primary circuit 4 being located inside the casing 3 and passing through the different compression, combustion and expansion element, the secondary circuit 5 being delimited radially inside by the casing 3 and outside by the fan shroud 2.
The rotation of the fan 1 inducing a swirl in the flow that it accelerates, it is known to position a flow straightener 6 in the secondary circuit 5, the straightener 6 including a plurality of vanes 7 configured to modify the direction of circulation of the flow in order to obtain axial flow downstream of the straightener 6.
The profile of the nacelles 2 is conventionally configured to form a nozzle downstream of the straightener and to accelerate and expand the secondary flow so as to generate the thrust, the cross section of the secondary circuit 5 decreasing downstream (in the case of a converging nozzle), then possibly re-increasing in the case of a converging-diverging nozzle.
In a turbomachine with separate flows, each flow is ejected by a nozzle. The nozzle (primary and secondary) transforms the potential energy into kinetic energy, i.e. it converts the pressure of the flow into ejection speed, which will generate thrust.
The secondary flow nozzle surrounds and is conventionally placed upstream of the primary flow nozzle. The primary flow nozzle is delimited by a cone, the point of which is directed downstream, and by an annular casing having a trailing edge oriented downstream. The cone and the casing define a circuit with a converging or converging-diverging section depending on the architecture selected.
The secondary nozzle is delimited by a duct belonging to the fan shroud (commonly called OFD or OFS, an abbreviation of “Outer Fan Duct/Shroud”) and to the turbomachine casing (currently called IFD or IFS, an abbreviation of “Inner Fan Duct/Shroud”). The two casings define a converging or converging-diverging section depending on the architecture of the rest of the engine.
This reduction of cross section is conventionally located downstream of the straightener 6, so as to accelerate the secondary flow as it streams axially, the secondary flow then being ejected around the primary flow.
In order to improve propulsive efficiency, it is desired to maximize the bypass ratio, i.e. the ratio of the mass flow rates of the secondary flow and of the primary flow, and therefore to minimize the compression ratio of the fan 1 for a given thrust.
The increase of the bypass ratio increases the diameter of the fan for the same thrust, which causes an increase in the volume and the weight of the fan shroud. Therefore, to limit this disadvantage, it is desired to reduce the fan shroud 2 to its strict minimum, in order to reduce its mass and the head losses of the secondary circuit 5, the effect of the head losses on the secondary flow being greater as the flow rate is greater, necessary for a high bypass ratio, and the pressure low, necessary for a low compression ratio of the fan 1.
Thus, the air inlet must be extremely short, and the fan shroud 2 must be as short as possible after the outlet of the blades 7 of the straightener 6.
One goal of the invention is to reduce the head losses induced by the fan shroud.
Another goal of the invention is to accelerate the secondary flow.
Another goal is to limit the head losses induced by the straightener.
Another goal of the invention is to increase the bypass ratio of the turbomachine.
Another goal is to reduce the compression ratio of the fan.
In order to achieve this, the invention proposes an assembly for a turbomachine extending along an axis and comprising:
This allows straightening and accelerating the flow propelled by the fan and transiting in a stream channel.
Advantageously, the invention can be completed by the following features, taken alone or in combination:
This allows accelerating the flow in a first portion of the stream channel, then slowing the flow in a second portion of the stream channel.
According to another aspect, the invention proposes a turbomachine including an assembly of this type.
Other features and advantage of the invention will be revealed by the description that follows, which is purely illustrative and not limiting, and must be read with reference to the appended figures in which:
The invention applies to a turbomachine comprising:
The flow thus circulating in the straightener 6 is accelerated in such a manner that it is no longer necessary to form a nozzle downstream of the straightener 6 between the fan shroud 2 and the ferrule 32.
It is therefore possible to significantly shorten the fan shroud 2, and therefore to reduce its mass, or to allow an increase of its diameter while retaining a mass substantially similar to a fan shroud 2 of the prior art.
This also allow reducing the head losses caused by the fan shroud 2.
In the entire text of this application, the notions of upstream and downstream are defined in the direction of the gas stream in the turbomachine.
The turbomachine extends along a turbomachine axis X, and the terms axial, radial and tangential refer to the axis X of the turbomachine. An axial direction follows the axis X of the turbomachine, a radial direction is perpendicular to the axis X of the turbomachine and a tangential direction is orthogonal to a radial direction and an axial direction.
In the embodiment shown in
In the embodiment shown, the ferrule 32 is located in the upstream continuation of the turbomachine casing 3.
In other embodiments, the ferrule 32 can be part of the casing 3, and thus form the upstream portion of the casing 3.
The ferrule 32 and the inner ferrule 31 can form only a single piece and form the leading edge of the casing 3.
In the embodiment shown in
The inlet section 14a, the ejection section 14b and the outlet section 14c extend respectively from the radially inner limit to the radially outer limit of the vanes 7.
The inlet section 14a thus corresponds to a radial section of the stream channel 13 which coincides with the leading edge 9 of the second vane 7b, and the ejection section 14b corresponds to a radial section extending downstream of the inlet section 14a.
The ejection section 14b has a surface area smaller than a surface area of the inlet section 14a and smaller than a surface area of the outlet section 14c.
This reduction in the cross section of the stream channel 13 allows accelerating the secondary flow as it circulates in the straightener 6.
The stream channel 13 has a radial section 14 which is defined as a virtual plane extending from the suction side wall 10a of the first vane 7a to the pressure side wall 11b of the second vane 7b while being normal to a mean stream direction at a central streamline F and extending substantially radially with respect to the longitudinal axis X.
What is meant by a central streamline is the streamline located equidistantly from the first vane 7a and from the second vane 7b.
The radial section 14 of the stream channel 13 has a surface area which decreases progressively between the inlet section 14a and the ejection section 14b.
More precisely, the radial section 14 has a width L defined as being a distance between the suction side 10a of the first vane 7a and the pressure side 11b of the second vane 7b for a constant distance from the axis X, and in which the width of the radial section 14 is decreasing along the circulation of the stream in the stream channel 13 between the inlet section 14a and the ejection section 14b.
In other words, the suction side wall 10a of the first vane 7a and the pressure side wall 11b of the second vane 7b are closer and closer to one another, for a given distance from the axis X, as the flow circulates from upstream to downstream in the stream channel 13.
This allows reducing the surface area of the radial section 14, which allows generating an acceleration of the flow.
This allows in particular reducing the surface are of the radial section 14 while avoiding strong variations of the profile of the fan shroud 2 and of the outer ferrule 32, so that perturbations and possible aerodynamic separations which can be generated by such variations are avoided.
In the embodiment shown, a radial section 14 has a shape comparable to an angular portion of a disk and has a dimension in a transvers direction and a dimension in a radial direction.
In the transverse direction, the radial section 14 is delimited by the first vane 7a and the second vane 7b.
The distance separating the first vane 7a and the second vane 7b, the width L, is a function of the distance to the axis X of the turbomachine at which the width L is considered. In fact, the distance between the first vane 7a and the second vane 7b increases with the distance to the axis X.
The result is that the width of a radial section 14 is a function of the radius or of a distance to the axis X of the turbomachine, and increases as a function of the distance to the axis X of the turbomachine.
In a radial direction, the radial section 14 is radially delimited internally by the outer ferrule 32 and extends over the entire height of a vane 7.
The radial section 14 has a radially internal limit and a radially external limit, each substantially forming a circular arc.
By moving the radial section 14 from upstream to downstream, the width L is reduced, and optionally the dimension in the radial direction is also reduced.
Thus, the reduction of the stream cross section 14 causes an expansion and therefore an acceleration of the secondary flow.
More precisely, the pressure side 11a of the first vane 7a and the suction side 10b of the second vane 7b are therefore configured so that the width L of a radial section 14, for a given distance to the axis X of the turbomachine, decreases with the downstream movement of the flow.
If a radial section 14 located downstream of the inlet section 14a is considered, the width L of the radial section 14 will be less than the width of the inlet section 14a.
It is obvious that, to compare the width of the inlet section 14a and the width L of the radial section 14, it is necessary that these two values be expressed for the same radius.
This width L can optionally be the length of a line segment joining the first vane 7b and the second vane 7a at mid-height.
Advantageously, for each radial section 14 between the inlet section 14a and the ejection section 14b, the length of the line segment joining the first vane 7b and the second vane 7a at mid-height decreases progressively between the inlet section 14a and the ejection section 14b.
The ejection 14b has the minimum surface area for a radial section 14.
In the embodiment shown, the width L of a radial section 14 decreases when moving from upstream to downstream until a median plane 15, the median plane 15 thus including the ejection section 14b.
In the embodiment shown, the median plane 15 is normal to the axis X of the turbomachine, and delimits the stream channel 13 into two portions, an upstream or intake portion 16 and a downstream or ejection portion 17.
If the radial section 14 is located in the intake portion 16, the transverse dimension of the radial section 14 is less than the transverse dimension of the inlet section 14a and greater than the transverse dimension of the ejection section 14b.
In other words, in the intake portion 16, the stream channel 13 is converging, the radial section 14 having a surface area that decreases from upstream to downstream.
This causes an expansion of the flow passing through the stream channel 13, and incidentally an acceleration of the flow.
The intake portion 16 of the stream channel 13 is configured to accomplish the work of modifying the flow direction and the acceleration of the flow.
The stream channel 13 thus has an inlet section 14a defining a plane normal (or orthogonal) to the stream direction of the flow deflected by the fan, this plane therefore not being normal to the axis X of the turbomachine, and an ejection section 14b defining a plane normal to the axis X of the turbomachine. This allows ejecting a flow circulating in a direction substantially parallel to the axis of the turbomachine.
In other words, the intake portion 16 straightens the flow while expanding it and while accelerating it until ejection at the median plane 15.
The ejection portion 17 is configured to minimize the aerodynamic drag of the straightener 6.
The incidence angle of the profile relative to the flow is small, so as to avoid separation of the air flow, while having the shortest length possible to minimize viscous friction.
A part of the ejection portion 17 is located downstream of the trailing edge 8 of the fan shroud 2. Thus, this allows slowing the flow in the ejection portion 17 until flight speed.
More specifically, downstream of the median plane 15, the profile of the vanes 7 is configured to minimize the drag of each vane 7, the vanes 7 therefore extending axially until their trailing edges 12.
The cross section of a van 7 downstream of the median plane 15, more particularly its dimension in the tangential direction, decreases downstream until its trailing edge 12, the reduction of the tangential dimension of the vane 7 being configured to limit aerodynamic separation.
Thus, the flows transiting the stream channels 13 located side by side join each other without aerodynamic separation.
The cross section of the flow channel 13 therefore increases downstream in the ejection portion 17.
Optionally, the vanes 7 have a camber line 71 which can include an inflection point, the camber line or mean line being defined in that it extends from the leading edge 9 to the trailing edge 12 and that it is at mid-distance from the suction side 10 and from the pressure side 11.
The camber line 71 has an inclination with respect to the axis X of the turbomachine corresponding to the swirl of the flow at the leading edge 9, and is substantially parallel to the engine axis of the median plane 15 at the trailing edge 12.
Advantageously, the median plane 15, and thus the ejection section 14b, coincides with the trailing edge 8 of the fan shroud. The ejection portion 17 is therefore not ducted. Thus, the length of the fan shroud 2 can be reduced to a minimum without penalizing the operation of the intake portion 16 which is ducted by the fan shroud 2, or the operation of the ejection portion 17, the only role of which is to reduce drag.
A portion of the vanes 7, particularly the trailing edge 12, is then located downstream of the trailing edge 8 of the fan shroud 2, and is therefore not ducted.
This allows minimizing the length of the fan shroud 2, and thereby minimizing the head losses induced by the fan shroud 2.
In one variant, the fan shroud 2 can continue axially beyond the median plane 15. In this configuration, the trailing edge 8 of the fan shroud 2 is situated downstream of the median plane 15 and upstream of the trailing edges 12 of the vanes, at a duct plane 18. This configuration allows forming a converging, then diverging profile in the ducted (i.e. covered by the fan shroud 2) portion of the stream channels 13. This allows improving performance, depending on the flight envelope.
Advantageously, each pair of adjacent vanes 7 of the straightener 6 defines a flow channel 13 configured to straighten and simultaneously to accelerate the flow, the vanes of the straightener 6 thus defining a plurality of stream channels 13 distributed circumferentially.
This allows accelerating the flow homogeneously over the entire circumference of the straightener 6.
In an assembly of this type, the absence of a nozzle formed by the fan shroud 2 and the ferrule 32 is compensated by the expansion effect of the straightener 6, more particularly by the expansion work accomplished by the intake portion 16 of the stream channels 13.
Head losses are reduced by the reduction of the length of the fan shroud 2 and the profile of the vanes 7, more particularly the trailing edge 12 and the profile of the ejection portion 17 allowing reducing the drag and thus limiting separation and head losses.
An assembly of this type thus allows straightening and accelerating the flow transiting in the stream channels 13, unlike conventional flow deflection elements.
Conventional straighteners straighten the flow and slow it down.
Conventional guide nozzles accelerate the flow while deflecting it, i.e. the flow arrives in the guide nozzle with a stream direction substantially parallel with the axis X of the turbomachine and leaves the guide nozzle with a stream direction that is inclined relative to the axis of the turbomachine.
Conventional nozzles form a converging channel which accelerates the flow without deflecting it.
In addition, the profile of the vanes 7 terminating with a trailing edge allows avoiding flow separation at the outlet of the assembly.
Number | Date | Country | Kind |
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1902662 | Mar 2019 | FR | national |
Filing Document | Filing Date | Country | Kind |
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PCT/FR2020/050524 | 3/12/2020 | WO |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2020/188197 | 9/24/2020 | WO | A |
Number | Name | Date | Kind |
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2798661 | Willenbrock, Jr. | Jul 1957 | A |
6502383 | Janardan | Jan 2003 | B1 |
7604458 | Ishii | Oct 2009 | B2 |
9759234 | Domereq | Sep 2017 | B2 |
20090056306 | Suciu et al. | Mar 2009 | A1 |
20180038235 | Damevin | Feb 2018 | A1 |
20210199019 | Wallin | Jul 2021 | A1 |
Number | Date | Country |
---|---|---|
2546422 | Jul 2017 | GB |
Entry |
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French Search Report dated Jan. 17, 2020 in French Application No. 1902662. |
International Search Report dated Oct. 15, 2020 in International Application No. PCT/FR2020/050524. |
Written Opinion of the International Searching Authority dated Oct. 15, 2021 in International Application No. PCT/FR2020/050524. |
Number | Date | Country | |
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20220186624 A1 | Jun 2022 | US |