The invention relates to a method for ventilating brake discs of an aircraft wheel.
Already known are aircraft whose wheels equipped with a brake are provided with a ventilator that can be controlled so as to cool the brake discs in order to rapidly lower their temperature and thus avoid any delay to the departure of the aircraft for a new cycle. In general, the body of the ventilator is engaged inside the axle bearing the wheel, and its turbine draws in the air through openings in the rim of the wheel. However, the ventilator arranged in this manner takes up a lot of space in the axle such that the spindle of the wheel speed sensor for measuring the speed of rotation of the wheel is elongated in order to pass through the ventilator and reach the wheel. Thus, this diminishes the measurements taken by the wheel speed sensor.
Also known, in particular in the automotive field, are turbines secured to the rim of the wheel in order to draw in air through the rim of the wheel. These turbines are for example integrated into a hub cap attached to the rim.
The invention has the object of proposing a method for ventilating brake discs of an aircraft wheel without either monopolizing the interior of the axle or obscuring the rim.
With a view to achieving this object, what is proposed is a method for ventilating discs of a brake fitted to an aircraft wheel having a rim mounted so as to rotate on an axle of a landing gear of the aircraft, the brake discs being threaded onto a torsion tube of the brake which extends around the axle, the method comprising the step of integrating a compressor into a space extending inside the torsion tube in order to draw in air beneath the torsion tube and to return the air thus drawn in by the compressor over the torsion tube towards the brake discs.
Thus, the compressor is completely integrated into the wheel, extending within a space located between the torsion tube and the axle, and therefore does not occupy the interior of the axle which is then free to receive a wheel speed sensor, and leaves the rim free for visual inspection thereof and access to the inflation valve. Advantageously, the wheel speed sensor may have a relatively small spindle, making it possible to improve the quality of its measurements.
The invention will be better understood in light of the following description, with reference to the figures of the appended drawings, in which:
The invention is relevant to an aircraft wheel 1 comprising a rim 2, in this case comprising two half-rims 2a, 2b that are assembled by bolts 3, and is mounted so as to rotate on an axle 4 by means of rolling element bearings 5 borne by a hub 6 of the rim 2. The wheel 1 is equipped with a brake 10 comprising brake discs 11, including stator discs 11a and rotor discs 11b, that are threaded onto a torsion tube 12 fixed to an axle flange 13 by means of bolts 14. The brake 10 comprises a support 15 for braking actuators 16 that are able to selectively apply a braking force to the stack of discs 11.
In accordance with a first embodiment of the invention, shown in
It will be noted that the web 7 of the half-rim 2a which extends so as to connect the hub 6 to the rest of the rim is closed and comprises no aeration openings that would allow the air flows to escape through the rim to the outside. This absence of alveoli simplifies the design of the rim. The half-rim 2a then acts as a deflector which forces the flow of air coming from the compressor 20 towards the brake discs 11.
With reference to
With reference to
In this case, the aeration openings 60 comprise no cover, such that part of the flow escapes through the rim to the outside, the other part of the flow of air being pushed between the brake discs 11 and the rim 2 to exit over the braking actuators 16.
According to a second embodiment of the invention, shown in
As was the case for the variants of the first embodiment, the web 7 of the half-rim 2a may, as a variant, comprise openings that are obstructed or not.
According to a third embodiment, illustrated in
As was the case for the variants of the first embodiment, the web 7 of the half-rim 2a may, as a variant, comprise openings that are obstructed or not.
According to a fourth embodiment, illustrated in
It can be seen here that the web 7 of the half-rim 2a comprises aeration openings 50 that are not obstructed.
By virtue of the centrifugal action of the compressor 50, the air is drawn in by the lower portion of the compressor 50 at the openings 53 of the volute 52, and is expelled over all 360 degrees of the exterior diameter of the compressor 50 so as to be delivered towards the interior of the rim. Then:
Thus, the air passes along a circuit inside the half-rim 2a on either side of the axle 4 and then on either side of the torsion tube, as indicated by the arrows in
As a variant, and as shown in
The invention is not restricted to that which has just been described, but rather encompasses any variant that falls within the scope defined by the claims.
In particular, although here the moving parts of the compressors rotate with the wheel, they may be motorized so as to rotate independently of the wheel.
Although the air drawn in by the compressor is returned over the torsion tube by the closed web of the wheel, it is possible to use wheels whose rims have openings (ventilation alveoli), possibly adapting a lightweight cover that is able to block these openings.
Although in this case the rotating blades are followed by stator vanes, the latter can be omitted such that the compressor then comprises only rotating blades.
In the case of the compressor comprising blades, these may equally be straight blades or blades which are curved, preferably in the preferred direction of rotation of the wheel.
Also, in the case of the compressor comprising blades, these may equally be short or long, whatever the compressor used.
In the case of a radial compressor, this may be designed such that the air is drawn in over all 360° of its inlet opening, or such that the air is drawn in only across an angular sector of its inlet opening. Preferably, the angular sector will then be arranged such that the compressor draws in air from its lower portion.
Furthermore, in the case of a radial compressor, this may be designed such that the compressed air is expelled over all 360° of its outlet opening, or such that the compressed air is expelled only across an angular sector of its outlet opening. Preferably, the angular sector will then be arranged such that the compressor expels the compressed air from its upper portion towards the top of the torsion tube and the upper web of the rim.
In the case of a radial compressor, as with an axial compressor, the method may comprise the additional step of associating a multiplier with the compressor, for example by arranging the multiplier between the wheel and the compressor.
Number | Date | Country | Kind |
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15 57958 | Aug 2015 | FR | national |