FR2824598A1 - Ventilation of turbojet nacelle is obtained by means of cavities in structural arms of enclosure in turbine rear and orifices in exhaust casing external scroll and in enclosure walls - Google Patents

Abstract

The nacelle (10) is located between a primary flow duct (11) of a hot flow (5) and a secondary flow duct (12) of a cold flow (6). Downstream is an exhaust casing (16) connected to an enclosure (17) located at the rear of the turbine by several structural arms (18) passing through the primary duct. Ventilation air is exhausted to the exterior by means of cavities (3) in the structural arms and orifices corresponding to the cavities in the external scroll of the exhaust casing and in the walls of the enclosure. The enclosure comprises an orifice (32) allowing the evacuation of ventilation air from the nacelle with the gases ejected from the turbine.

Description

claims 14 to 26.

  The invention relates to the internal ventilation of the nacelle

  surrounding the body of a turbojet engine.

  More specifically, it relates to an internal ventilation device for the nacelle of the body of a turbofan with double flow, this nacelle of the body being disposed between a primary flow vein for a hot flow and a secondary flow vein for a cold flow, and comprising downstream, in the direction of gas flow, an exhaust casing connected to an enclosure arranged at the rear of the turbine by a pl u rality of structural arms crossing the pr vein ma i re, led it device comprising means for exhausting ventilation air

outwards.

  This nacelle, known as the body in the present specification, by analogy with the so-called blower nacelle which surrounds the blower and extends downstream in the direction of gas flow in order to externally delimit the secondary flow vein of cold flow, has an external cover which internally delimits the cold flow vein, and an internal casing which externally delimits the primary vein. This internal casing is made upstream and downstream by the casings of the low pressure and high pressure compressors, the casing of the combustion chamber, the casings of the high pressure and low pressure turbines, and finally the outer shell of the exhaust casing. The casings of the high-pressure and low-pressure turbines are fitted with crowns of fixed blades which extend radially towards the axis of rotation of the turbojet engine in the primary stream in a region where the high temperature gases circulated by the combustion chamber circulate. . Movable blade crowns mounted on the turbine rotors are interposed between the fixed blade crowns. In order to improve the performance of the engine, it is necessary to adjust the clearances between the ends of the moving blades and the turbine casings. This is done in particular by cooling the elements subjected to high temperatures by means of cooling air taken off.

  in stages of low pressure and high pressure compressors.

  The internal cavity of the nacelle of the body contains a plurality

  of ducts, in particular the air intake ducts for cooling

  distribution of the turbine casings and the air conditioning and pressurization of the aircraft cabin, the fuel delivery pipes to the combustion chamber, the oil delivery pipes to the rotor bearings and the return pipes oil. This cavity also contains the means for attaching the turbojet engine to a pylon. The pylon partly extends into the cavity and must be protected against the risk of fire. The whole of the pylon and its protection occupies a cavity sector which extends substantially over 90 and which is arranged in the vicinity of the structural arms supporting the enclosure and the bearings of the turbines. The section of the nacelle of the body surrounding the structural arms is therefore partially occupied by the pylon. This section is on the one hand subjected to high temperatures and considerable mechanical stresses due to the axial forces applied by the bearings and

  taken up by the pylon through the structural arms.

  The cooling air of the turbine casings is exhausted inside the nacelle of the body after use. To prevent this heated air from returning to the front area of the nacelle, the walls of which are in contact with cold fluids, means are provided for discharging the air contained in the nacelle downstream of the turbine sections. These evacuation means are produced in the form of orifices or conduits which put the interior of the nacelle into communication with the exterior of the turbojet engine where an ambient pressure is lower than the pressure

  reigning inside the nacelle of the body.

  These orifices or evacuation conduits are currently provided in the external cover of the nacelle in a transverse plane perpendicular to the axis of rotation of the engine, located substantially at right

  structural arms of the exhaust casing.

  When the turbojet engine is equipped with a short fan nacelle, the orifices are provided in an angular sector of 270, the ends of which are arranged on either side of the pylon sector. The cooling air of the nacelle of the body is thus evacuated at the outlet of the

secondary vein.

  When the turbojet engine is fitted with a long fan nacelle which forces the cold gases from the secondary stream to mix with the chaub gases from the primary stream at the outlet of the exhaust casing, it is generally provided on the side opposite the pylon an evacuation duct crossing the secondary vein and opening into the external cover of the

blower nacelle.

  The presence of the pylon and the provisions currently applied for the exhaust of gases circulating in the nacelle of the body cause thermal heterogeneity of the line of the high and low pressure turbine casings which leads to degraded performance by opening the games at the top blades, and creates a thermal gradient

  high in the exhaust casings which limits their lifespan.

  In addition, the structural arms supporting the enclosure are not ventilated. However, these structural arms contain the supply and oil recovery tubes of the rear enclosure, and are in contact with the hot exhaust gases. There are therefore risks of coking in these tubes, which can be detrimental for the lubrication of the turbine bearings. The object of the invention is to propose a device for ventilating the nacelle of the body as mentioned in the introduction which makes it possible to improve the overall performance of the turbojet engine and to increase the life of the exhaust casing and of the components of the nacelle by a substantial decrease in the temperature of these components and

including structural arms.

  The invention achieves its object by the fact that the exhaust means are formed by cavities formed in the structural arms and orifices formed in correspondence with said cavities in the outer shell of the exhaust casing and in the walls of the enclosure, said enclosure comprising in particular in the axis of rotation of the turbojet engine an orifice allowing the evacuation of the ventilation air

  in the turbine exhaust gases.

  Advantageously, the cavities of the structural arms are

  supplied by an annular collector provided at the head of the arms.

  Preferably, the manifold has air inlets

  arranged circumferentially alternately with the structural arms.

  Thus the air taken from the nacelle of the body makes it possible to effectively cool the outer shell of the exhaust casing as well as the structural arms. In order to further cool the structural arms, the walls

  internal of the latter may be fitted with disturbers.

  Other advantages and characteristics of the invention will emerge

  on reading the following description given by way of example and in

  reference to the accompanying drawings, in which: FIG. 1 is an axial section of a turbofan engine equipped with the device for ventilating the nacelle of the body according to the invention; Figure 2 is a cross section of the turbojet engine of Figure 1 to the right of the exhaust casing arms; and Figure 3 is a substantially axial section taken along the

lO lil-lil line of figure 2.

  FIG. 1 shows a turbofan 1 having a double fan at the front, driven by a shaft 3 of axis X and surrounded by a fan nacelle 4. The air flow sucked by the fan 2 is divided into downstream of the blower in the direction of air flow, in a primary flow 5 and a secondary flow 6. The air in the primary flow passes successively through a compression section 7, where it is compressed, a section combustion 8, where it is mixed with fuel and burnt, then a turbine section 9, o the gases from the combustion section are expanded and produce work involving in particular the shaft 3 of the fan 2, and finally a gas ejection section. A nacelle of the body 10, of elongated and annular shape, separates the primary vein 11 in which the primary flow 5 flows and the secondary vein 12 in which the secondary flow 6 flows. The primary 5 and secondary 6 flows can be join downstream of the ejection section. The nacelle of the body 10 comprises a turbojet engine casing 14 on the side of the primary stream 11 and an external cover 15 on the side of the secondary stream 12, and has downstream of the turbine section 9 an annular exhaust casing 16 internally supporting an enclosure 17 by means of a plurality of structural arms 18 passing through the primary stream 11. The enclosure 17 comprises in particular in the axis of rotation X of the fan 2 turbine support bearings, and has downstream a

base 19.

  The reference 20 represents means for attaching the core nacelle 10 to a pylon not shown in the drawings. These attachment means 20 are arranged inside the nacelle of the body 10 slightly upstream of the exhaust casing 16 and of the structural arms 18. A flow of cooling air F1 from the nacelle of the body 10 is taken from the compression section 7 and flows axially towards

  downstream inside the nacelle 10.

  The casings of the turbine section 9 are also cooled by an additional flow of cooling air taken from the compression section 7 and guided by specific conduits. After use, this secondary flow is evacuated inside the nacelle of the

  body 10 and mixes with the air flow F1.

  According to the invention, the interior of the nacelle of the body 10 is placed in communication with the exterior by cavities 30 formed in the structural arms 18, orifices 31a and 31b formed in correspondence in the internal walls of the joint 17 , and an axial orifice 32 provided at the downstream end of the base 19. The flow of cooling air F1 escapes

  thus axially in the turbine ejection gases.

  As can be seen in FIGS. 2 and 3, the reference 33 represents an orifice formed in the external shell 34 of the exhaust casing 16 at the head of a structural arm 18. Each arm 18 is thus supplied with air by an orifice 33. These orifices 33 open into an annular manifold 35 surrounding the heads of the structural arms 18. This annular manifold 35 is supplied with air by air inlets 36 arranged circumferentially alternately with the structural arms 18. In other words, each inlet of air 36 is disposed substantially equidistant from the orifices 33 for entry into the cavities 30 of two adjacent structural arms 18. The air inlets 36 are arranged inside the nacelle of the body 10 at a short distance from the outer shell 34. The section of the annular manifold 35, of generally rectangular shape, is chosen so as to ensure intensive cooling of the external shroud 34 of the exhaust casing 16. In order to further promote the cooling of the structural arms 18, the internal wall of the latter can be fitted with disturbers or pins 37, similar to those

  used in the stationary blades of a high pressure turbine.

  In a turbojet engine of the type described above, the temperature of the air in the core nacelle 10 is approximately 250 ° C., the temperature of the exhaust gases in line with the radial arms 18 is approximately 700 ° C. In current turbojet engines, the structural arms 18 are not ventilated. The outer shell 34 is at a temperature of approximately 650 C, the arms 18 are at a temperature close to 700 C, and the enclosure 17 is at

a temperature of 500 C.

  By equipping the same turbojet with an exhaust air circuit F1 for the nacelle of the body 10, passing through the annular manifold 35, the cavities 30 of the radial arms 18 and the orifices 31a, 31b and 32 of l enclosure 17, a lowering of the temperature of the outer shell 34 and of the structural arms 18 of at least C can be expected, and a lowering of the temperature of the enclosure 17 greater than C. This can be obtained with an annular collector 35 having a thickness of 4 mm and an axial dimension of 200 mm, and orifices 33 having an axial dimension of 60 mm and a width of between 6 and mm. The decrease in temperature of the structural arms 18 and of the external role 34 increases the service life of these parts, or the possibility

  to use other less expensive materials.

  The small thickness of the annular collector 35 allows its installation without problem inside the nacelle of the body 10, in particular opposite the pylon head. The supply of the manifold 35 by the air inlets 36 angularly distributed around the axis X promotes an axial circulation of the flow of cooling air F1 inside the nacelle of the body 10. The temperatures at the outer shell 34

  are more homogeneous than those obtained in the state of the art.

  The invention also allows a decrease in variations in

  40% temperature in transient mode.

Claims (4)

  1. Device for internal ventilation of the nacelle of the body (10) of a turbofan engine, this nacelle of the body (10) being disposed between a primary stream (11) for the flow of a hot flow (5), and a secondary stream (12) for the flow of a cold flow (6), and comprising downstream, in the direction of the flow of the gases, an exhaust casing (16) connected to an enclosure (17) disposed at the rear of the turbine by a plurality of structural arms (18) passing through the primary stream (11), said device comprising means for exhausting ventilation air to the outside, characterized in that the means exhaust are formed by cavities (30) formed in the structural arms (18) and orifices (31a, 31b, 33) formed in correspondence with said cavities (30) in the outer shell (34) of the exhaust casing (16) and in the walls of the enclosure (17), said enclosure (17) comprising in particular in the axis of rotation (X) of the tu jet engine an orifice (32) allowing the evacuation of the ventilation air from the nacelle (10) in the turbine exhaust gas.   2. Device according to claim 1, characterized in that the cavities (30) of the structural arms (18) are fed by a collector   annular (35) provided at the head of the arms (18).   3. Device according to claim 2, characterized in that the collector (35) comprises air intakes (36) arranged circumferentially   alternately with the structural arms (18).   4. Device according to one of claims 1 to 3, characterized   by the fact that the internal walls of the structural arms (18) can be