The invention relates to a heat exchanger of an air circulation channel of a turbomachine.
Such an exchanger is particularly suited to be installed in a turbomachine of an aircraft and, more specially, an aircraft turbojet.
A turbomachine comprises many elements such as roller bearings that support the shaft or shafts of the turbomachine, which require being both lubricated and cooled. Also, it is known to supply these elements with “cold” oil.
As such, certain turbomachines are provided with a surface air-oil exchanger of the SACOC (Surface Air-Cooled Oil-Cooler) type, arranged in an air circulation channel of the turbomachine. In this SACOC type air-oil exchanger are arranged a multitude of channels wherein circulates the oil to be cooled. The exchanger comprises a corps surmounted with fins that have an isosceles trapezoidal profile. These fins increase the heat exchange surface between the oil to be cooled circulating in the channels of the body and the air circulating in the air circulation channel of the turbomachine. However, these fins also generate undesirable load losses.
The invention makes it possible to improve the heat exchangers of a known type and relates to this effect to a heat exchanger for an air circulation channel of a turbomachine, with the heat exchanger being configured to be passed through by a fluid to be cooled and comprises a plurality of fins that protrude with respect to a support surface, each fin extends axially over a length in the direction of the circulation of air and comprises a leading edge and a trailing edge, the heat exchanger being characterised in that each fin further comprises a central body, between the leading edge and the trailing edge, with the central body having in a plane parallel to the support surface a curved central profile.
The invention is advantageously supplemented by the following characteristics, taken individually or in any technically permissible combination of them:
The advantages of the invention are multiple.
The curved profile of the fin makes it possible to reduce the length of the latter, while still retaining the same exchange surface. Consequently, the length of the exchange device in contact with the fins (oil ducts inside) is also reduced which makes it possible to optimise its isothermal exchange mass.
In particular, in the case where the air circulation channel is a secondary stream of a turbomachine, the shape of the fins makes it possible to absorb the residual gyration. Indeed, the fan creates a gyrating flow, and although the outlet rectifier vanes, more commonly known as OGV, rectify the flow in order to align it with the drive shaft, there still subsists a residual gyration. There is residual gyration if the flow of the fluid behind the OGVs is according to a non-zero angle with respect to the drive shaft.
Other characteristics, purposes and advantages of the invention shall appear in the following description, which is solely for the purposes of illustration and is not restricted, and which must be read with regards to the annexed drawings wherein:
In all of the figures, similar elements bear identical references.
In what follows, “turbomachine” means any machine that makes it possible to convert the thermal energy of a working fluid into mechanical energy by expansion of said working fluid in a turbine. More particularly, this working fluid can be a combustion gas resulting from the chemical reaction of a fuel with air in a combustion chamber. As such, the turbomachines, such as described here, comprise single-spool or twin-spool turbojets, turboprops, turboshaft engines or gas turbines, among others.
In what follows, the terms “upstream” and “downstream” are defined with respect to the normal direction of circulation of the air in the air circulation channel of the turbomachine.
The intermediate casing III comprises a intermediate casing ferrule 14, a flow separator 15 that radially separates the primary stream V1 of the gases from the secondary stream V2 of gases, with the ferrule 14 and the flows separator 15 being connected by portions of rectifier vanes 104a. Of course, in the case where the turbomachine is a single-stage turbojet, the intermediate casing does not have a flow separator.
The fan casing II and the intermediate casing III are covered, on the outside, by an exterior cowl 17, generally called a “fan cowl”, extending axially and azimuthally around the fan casing II and the intermediate casing III. This exterior cowl 17 provides for the geometrical continuity of the exterior of the turbomachine 100 between the air inlet casing I and the exterior IVa of the thrust reverser casing IV.
In what follows, it is considered that the air circulation channel in the sense of the invention is related for example to the secondary stream V2 of the turbomachine shown in
The turbomachine comprises a heat exchanger 12. In this example the heat exchanger is an air-oil heat exchanger 12 of the SACOC type. In the example, the heat exchanger 12 is arranged at the inlet of the air circulation channel 10.
In the rest of the description, the invention shall be described for any air circulation channel of a turbomachine delimited by a first structure 18 and a second structure 19 that can be respectively the ferrule 14 and the flow separator 15.
The direction wherein the air circulates in the air circulation channel 10 is materialised by the arrow A.
The heat exchanger 12 comprises, in this example, a body 21, which is a part of the first structure 18. The heat exchanger 12 is therefore partially integrated to the first structure 18 and is able to be partially annular in order to correspond to the ferrule 14. In other embodiments, the heat exchanger 12 can be partially integrated to the second structure 19.
The heat exchanger 12 comprises fins 20 connected to the body 21. Each fin 20 is protruding with respect to the first structure and extends in height in the air circulation channel 10. The fins 20 are more preferably parallel to one another. The first structure is hereinafter referred to as “support surface”,
The body 21 of the heat exchanger 12 comprises a inlet channel 24 of “hot” oil to be cooled, a plurality of channels 26 wherein circulates the “hot” oil, as well as an outlet channel 28 making it possible to recover the “cold” oil. The body 21 of the heat exchanger 12 can however comprise other inlet, circulation and outlet channels for the “hot” oil,
As can be seen partially in
The fins 20 are arranged on channels 26 for the circulation of the “hot” oil. The “hot” oil that arrives in the body 21 of the exchanger 12 and which requires cooling, passes through the plurality of circulation channels 26. The heat given off by the “hot” oil is transferred to each fin 20 protruding in the air circulation channel 10 wherein cold air circulates. As such, the thermal energy “stored” in each fin 20, is transferred via a heat exchange surface from each fin 20 to the “cold” air,
As shown in
Moreover, as shown more specifically in
As is shown in
Each fin 20 has a thickness e between 1 mm and 3 mms.
Furthermore, as is shown in
Each fin 30 as such comprises a leading edge 30 that has a leading profile PR1, a central body 37 that has a central profile PR2 and a trailing edge 32 that has a trailing profile PR3.
Advantageously, the leading edge 30 has a leading profile PR1 in the plane P′ parallel to the support surface forming an acute angle α with an axis parallel to the main axis X of the turbomachine. This angle α is between 2° and 10°, typically between 3° and 4°.
Such a leading edge 30 which is not oriented parallel to an axis parallel to the main axis X of the turbomachine but which is offset with respect to the latter makes it possible to absorb a residual gyration of the OGVs in the case where the air circulation channel 10 corresponds to a secondary stream V2 of a turbojet. Indeed, the fan creates a gyrating flow, and although the outlet rectifier vanes, known more commonly as OGVs, rectify the flow in order to align it with the drive shaft, there still subsists a residual gyration. There is residual gyration if the flow of the fluid behind the OGVs is according to a non-zero angle with respect to the drive shaft.
As such, in order to progressively rectify the flow coming from the leading edge the curved central profile PR2 of the central body 37 of the fin 20 is preferably defined by a Bezier curve such that
with u a parameter varying from zero to one in order to characterise a point of the curve, Pi the coordinates in the plane P′ parallel to the surface 14 support of control points of the Bezier curve and n the number of control points.
The junction of the profiles PR2 and of the profile PR1 advantageously has a continuity so as to contribute in limiting the load losses and progressively rectify the flow coming from the leading edge.
Finally, in order to guide the flow coming from the central body 37 parallel to the main axis X of the turbomachine, the trailing edge has a trailing profile PR3 parallel to the direction of the circulation of the air. In other word, the profiles PR1 and PR3 therefore do not have the same orientation and form an acute angle α between 2° and 10°, typically between 3° and 4°.
Preferably, the leading edge 30 represents between 10% and 20% of the length L of the fin 20, and/or the central body represents between 70% and 85% of the length L of the fin 20 and/or the trailing edge represents between 5% and 10% of the length L of the fin 20.
In relation with
In this figure, the Bézier curve comprises four control points P0, P1, P2, P3. In particular, the first point P0 is placed at 0% of the central body 37 (i.e. at the very beginning of the central body 37) the fourth point P3 is placed at 100% of the central body 37 (i.e. at the end of the central body 37). The second point P1 can be placed between 0% and 70% of the central body 37, the third point P2 is placed according to the position of the second point P1 and can be placed between 20% and 100% of the central body. It is therefore possible that the third point P2 be confounded with the second point P1, with the curve then being defined by three points.
The location of these points is adapted so that the distribution of the curvature minimises the load losses and adapts to the fin length chosen. If the fins have to be shorter, the curvature is increased in order to provide the same exchange surface. The control points are located on the same side of the curve on
Number | Date | Country | Kind |
---|---|---|---|
14 00220 | Jan 2014 | FR | national |
Number | Name | Date | Kind |
---|---|---|---|
3886639 | Pasternak | Jun 1975 | A |
5984636 | Fahndrich et al. | Nov 1999 | A |
6313399 | Suntio | Nov 2001 | B1 |
6698511 | DiBene, II | Mar 2004 | B2 |
7079390 | Barr | Jul 2006 | B2 |
9238284 | Swinford | Jan 2016 | B2 |
20120114467 | Elder | May 2012 | A1 |
20120237332 | Bulin et al. | Sep 2012 | A1 |
20130153184 | Rolt et al. | Jun 2013 | A1 |
20150315923 | Bordoni | Nov 2015 | A1 |
Number | Date | Country |
---|---|---|
2 607 831 | Jun 2013 | EP |
WO 9932761 | Jul 1999 | WO |
WO 2010136710 | Dec 2010 | WO |
WO 2013150248 | Oct 2013 | WO |
Entry |
---|
French Preliminary Search Report and Written Opinion dated Oct. 22, 2014 in Patent Application No. 1400220 (with English translation of categories of cited documents). |
Number | Date | Country | |
---|---|---|---|
20150211801 A1 | Jul 2015 | US |