The invention relates to a turbine engine flow straightening assembly, and a turbine engine comprising such an assembly. The invention applies particularly to turbine engines of the double flow type.
A double flow turbine engine for aeronautical propulsion is shown in
The peripheral portion, called the secondary flow FS, of the air flow is for its part injected into the atmosphere to supply the major portion of the thrust of the turbine engine 1, after having passed through a fixed blade assembly 20 disposed downstream of the fan. This assembly, called a straightener 20 (also known by the acronym OGV for “outlet guide vane”), allows the secondary air flow to be straightened at the outlet of the fan, while still limiting losses as much as possible.
Shown on the same figure is a structural arm 30, which connects the external collar of the intermediate casing to the internal collar of the intermediate casing, thus contributing to supporting and maintaining in position the engine shaft(s) and ensuring the structural resistance of the assembly. The structural arms also have the function of allowing the transmission of movement or of fluids between the turbine engine and the rest of the aircraft on which it is mounted. To this end, the structural arms are hollow, and allow the accommodation of pipes, transmission shafts, etc.
In order to improve the aerodynamic performance of a double flow turbine engine, it is desired to increase the bypass ratio of the turbine engine, i.e. the ratio between the flow rate in the secondary stream and the flow rate in the primary stream.
Now the presence of the structural arm 30 and other intruding mechanical members protruding into the secondary stream perturb the flow of air in the secondary stream and limit the improvement of the bypass ratio.
In fact, the outer diameter of the turbine engine is constrained by the integration of the totality of the elements under the wing of the airplane to which the turbine engine is attached, while still maintaining sufficient clearance between the bottom of the turbine engine once suspended under the wing and the ground (particularly sufficient clearance to pass over the lights installed on the takeoff and landing runways). For this reason, certain members sometimes protrude into the secondary stream.
The structural arm being frequently the accommodation of a radial transmission shaft, the protruding members inside the secondary stream can comprise, at one end of this arm, an angle transmission gearbox (or TGB for Transfer GearBox) or an intermediate gear transmission for driving the radial shaft (or IGB for Intermediary GearBox).
It is therefore necessary to compensate for the detrimental aerodynamic consequences of these problems of integrating mechanical elements.
The invention therefore has as its aim to propose a turbine engine air-flow straightening assembly, particularly for double flow turbine engines, having improved aerodynamics.
In this regard, the invention has as its object a turbine engine air-flow straightening assembly comprising:
The proposed fairing allows, by covering in the mechanical members protruding into the air flow stream, while still offering tangency continuity between the surface of the fairing and the support platform of the straightener blades and of the structural arm, limiting the perturbations of the air flow in the stream.
The application of such an assembly to a double flow turbine engine therefore allows a better bypass ratio.
The fact of proposing a limited slope on the downstream side of the fairing also allows the occurrence of aerodynamic separation to be limited.
Finally, the fairing extends from at least a quarter of the chord of the straightener blade to limit the blockage of the stream as well as the propagation of distortion of static pressure.
Other features and advantages of the present invention will appear upon reading the description that follows of a preferred embodiment. This description will be given with reference to the appended drawings in which:
Referring to
The platform 15 is therefore a collar centered on an axis X-X, this axis being the main axis of the turbine engine.
The assembly also includes at least one straightener blade 20 extending from the platform, radially around the axis X-X,
The straightener blade 20 includes a leading edge 21, the axial position of which is denoted xBA, a trailing edge 22, and a chord cOGV, which is the distance, measured in the direction of the axis X-X, between the leading edge 21 and the trailing edge 22.
In addition, the assembly comprises a structural arm 30.
The structural arm is advantageously, but without limitation, of the “integrated straightener blade” type, i.e. it comprises an upstream end portion 31 having the profile of a straightener blade. This is the case in the example shown in
The structural arm 30 also comprises a hollow zone 32 called forbidden by design (or KOZ for Keep-Out Zone) which is an accommodation dedicated to the installation of mechanical elements necessary to the operation of the turbine engine such as utilities, and particular for accommodating pipes, for example for oil or fuel, mechanical connections, one or more transmission shafts, etc.
The assembly also comprises a mechanical member 40 protruding into the air flow stream from the platform 15. This mechanical member is located at one end of the structural arm 30 and, for reasons of integration indicated in the introduction, emerges in the interior of the stream.
The mechanical member 40 can comprise, in the case where the structural arm 30 accommodates a radial transmission shaft, one end of this shaft, an angle transmission gearbox of this shaft (or Transfer Gear Box) or an intermediate gear transmission for driving this shaft (or Intermediary Gearbox). In the case where the structural arm 30 accommodates utilities, the mechanical member 40 can also or alternatively comprise electrical, hydraulic (oil or kerosene pipes) or pneumatic connection elements.
The assembly also comprises a fairing 50 of the protruding mechanical member, i.e. a wall covering this member by presenting an aerodynamic shape limiting the perturbations of the air flow flowing in the stream.
In this regard, the fairing has a three-dimensional surface; the geometry of which depends on that of the mechanical member 40.
The mechanical member 40 is parameterized by:
Then the three-dimensional surface of the fairing 50 is also parameterized by a set of points.
Ai and Ae denote the upstream end points with respect to the air flow of the three-dimensional surface of the fairing 50, respectively on the pressure side and on the suction side of the structural arm 30.
The upstream end points Ai and Ae are preferably aligned axially but a clearance is allowed such that their axial positions are distant by at most a tenth of the chord of the straightener blade:
xAi=xAe±0.1cOGV
In order to cover the mechanical member 40, each upstream end point is located upstream of the upstream end of the mechanical member 40:
xAi,e<x1KOZ
Moreover, as shown in
Moreover, so as not to perturb the flow of air at the inlet of the stream, the axial position of each upstream end point is advantageously distant from the leading edge 21 of the straightener blades 20 by at least a quarter of the chord of the blade:
xBA+0.25cOGV≤xAi,e<x1KOZ
Denoted Ci and Ce are the downstream end points with respect to the air flow of the three-dimensional surface of the fairing 50, respectively on the pressure side and the suction side of the structural arm.
The downstream end points Ci and Ce are preferably aligned axially, but a clearance is allowed such that their axial positions are distant by at least a tenth of the chord from the straightener blade:
xCi=xCe±0.1cOGV
In order to cover the mechanical member 40, each downstream end point of the surface of the fairing 50 is located downstream of the downstream end of the mechanical member 40:
x2KOZ≤xCi,e
Moreover, as shown in
The three-dimensional surface of the fairing 50 is also parameterized by two maximum-height points Di, De measured radially with respect to the axis X-X, respectively on the pressure side and on the suction side of the structural arm. The radial distance of these points with respect to the axis is denoted respectively rDi and rDe, and xDi and xDe their axial positions. The maximum-height points Di, De have the same axial position as the maximum-height point hKOZ of the mechanical member 40.
In order for the three-dimensional surface to cover the mechanical member 40, we have:
rDi,e≥hKOZ
However, to limit the blockage of the fairing in the stream, the heights of the points Di, De are as small as possible. Advantageously, we have:
1.25hKOZ≥rDi,ehKOZ
The points Di, De are advantageously aligned axially, within a tenth of the chord of the straightener blade 20:
xDi=xDe±0.1cOGV
Advantageously, the axial position of the downstream end points is adapted to that of the maximum-height points to limit the slope of the three-dimensional surface to less than 30%. The minimization of the slope allows reducing unfavorable pressure gradients and minimizing flow separation.
Finally, the three-dimensional surface is parameterized by two lateral extreme points Bi, Be. These points correspond to the ends of the largest cross-section of the mechanical member 40 measured along the axis Y-Y. The axial positions of these point are denoted xBi and xBe, and yBi and yBe their position along the axis Y-Y with respect to the center of the prohibited by design zone 32.
In order for the three-dimensional surface to cover the mechanical member 40, we have:
yBi≥yiKOZ
yBe≥yeKOZ
However, the maximum blockage along the axis Y-Y, and therefore the positions yBi and yBe, are constrained by the width sOGV of the channel between the structural arm 30 and the adjoining straightener blade 20: yBi,e≤sOGV.
The points Bi, Be are advantageously aligned axially, within a tenth of the chord of the straightener blade 20:
xBi=xBe±0.1cOGV
As can be seen in
Moreover, the axial positions of the lateral extreme points and of the maximum-height points are advantageously distant by a tenth of the chord of the straightener blade 20 at most.
The parameterization indicated previously therefore allows the aerodynamic performance of the secondary stream of a double flow turbine engine to be preserved, and therefore to improve the bypass ratio, without impacting the ground clearance of the aircraft on which the turbine engine is installed.
Number | Date | Country | Kind |
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15 57262 | Jul 2015 | FR | national |
Filing Document | Filing Date | Country | Kind |
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PCT/FR2016/051990 | 7/29/2016 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2017/017392 | 2/2/2017 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
9068460 | Suciu | Jun 2015 | B2 |
20120093642 | Nilsson et al. | Apr 2012 | A1 |
20130259672 | Suciu et al. | Oct 2013 | A1 |
Number | Date | Country |
---|---|---|
2878796 | Jun 2015 | EP |
3010154 | Mar 2015 | FR |
2014018137 | Jan 2014 | WO |
2017017392 | Feb 2017 | WO |
Entry |
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Preliminary Research Report received for French Application No. 1557262, dated Jun. 16, 2016, 3 pages (1 page of French Translation Cover Sheet and 2 pages of original document). |
International Search Report and Written Opinion received for PCT Patent Application No. PCT/FR2016/051990, dated Nov. 28, 2016, 22 pages (10 pages of English Translation and 12 pages of Original Document). |
International Preliminary Report on Patentability received for PCT Patent Application No. PCT/FR2016/051990, dated Feb. 8, 2018, 17 pages (9 pages of English Translation and 8 pages of Original Document). |
Number | Date | Country | |
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20180231025 A1 | Aug 2018 | US |