The present invention relates to a mechanical gear transmission, in particular for aeronautical purposes. In the aeronautical field, the use of traditional or epicyclic mechanical gear transmissions is very common.
As it is known, mechanical transmissions are cooled and/or lubricated with lubricant-refrigerant oils, so as to increase their duration and obtain, at the same time, reliability even in the case of particularly high transmitted powers.
Furthermore, as it is known, a part of the lubricant oil inevitably leaks out in an axial direction through the teeth and flows outwards as a result of a centrifugal effect. Therefore, in use, a flow of drawn oil is formed, which must be collected and led to the tank, not only to avoid fluid leaks and high managing costs, but also to prevent said drawn oil from becoming, in turn, a source of additional leaks caused by the drawn oil hitting the rotary elements of the transmission.
To this aim, it is known to use external collectors to collect and channel the drawn oil; the oil collected in said external collectors is quickly led towards the oil suction area, filtered and reintroduced in the system.
Known collection collectors, despite being able to partly fulfil the main function of collecting the drawn oil, have proven to be not good enough for the following reasons.
First of all, current collection collectors cannot avoid the formation of splashes and the return of the drawn oil towards the rotary elements and, in general, they are not able to limit fluid-dynamic leaks due to the drawn oil hitting the rotary organs.
In addition, known collection collectors are generally sized taking into account the nominal operating conditions of the transmission. For this reason, known collection collectors turn out to be ineffective when the transmission operates in so-called “off-design” conditions, namely with a rotation speed that is smaller than the nominal or normal operating rotation speed.
Finally, known collection collectors often require strict tolerances and clearances in the coupling with rotary parts that complicate both their manufacturing process and their assembly, often because of the need to provide mechanical seals to intercept oil splashes.
The object of the present invention is to provide a mechanical gear transmission, which has manufacturing features that help solve the above-mentioned problems in a simple and low-cost manner and, at the same time, besides being efficient and reliable, is also easy and economic to manufacture.
According to the present invention, there is provided a mechanical gear transmission as claimed in claim 1. Preferably, in the transmission described above, said first and second annular concave portions and said wall are integrally connected with each other.
The invention will now be described with reference to the accompanying drawings, which show some non-limiting embodiments thereof, wherein:
In
The transmission 1 also comprises, an external ring gear 6, which is arranged coaxially to the axis 5 and has an internal toothing 7.
In
In the transmission 1, the toothing 7 of the ring gear 6 engages with the toothing 9 of one or more intermediate ring gears 10, which, in turn, engage with the central ring gear 3 and rotate around respective axis 10A, which are fixed relative to the frame 2 and parallel to the axis 5. With reference to
The collection collector 11, which is part of a lubrication circuit for the ring gears, is defined by an annular hollow body, which is preferably manufactured in one single piece of metal material or is made up of different portions made of the same material or of different materials, which are connected to each other in a known manner.
The collection collector 11 is stably connected, in a known manner, to the frame 2 in a position surrounding the tubular portion 8B.
In the embodiment described herein, the collection collector 11 comprises two annular half-shells 12, which are mirror-like relative to a radial plane 13, which is orthogonal to the axis 5 and substantially passes through the middle of the ring gears 3 and 10. According to a variant that is not shown herein, the collection collector 11 does not have radial symmetry planes and the two half-shells are different from one another in terms of geometry and sizes, so as to adjust to the arrangement and to the manufacturing features of the ring gears.
In the embodiment described herein, the collection collector 11 comprises an external central concave portion 14, which is V-shaped and comprises, in turn, two sections 15, which extend starting from the plane 13 and each makes up part of a relative half-shell 12.
The portion 14 has a concavity turned towards the ring gear 6, so as to collect an oil mass M moved as a result of a centrifugal effect. The collection collector 11 also comprises, two lateral concave portions 16, which are arranged on opposite sides of the plane 13 and each makes up part of a respective half shell 12.
Each concave portion 16 has a concavity turned towards the concave portion 14, houses, in use, a relative lubricant oil mass, and is stably connected in a fluid-tight manner to a respective section 15 of the concave portion 14 itself by means of a relative wall 18 defining a deflector screen, which is designed to channel a part of the oil drawn or is present in the concave portion 14 on the inside of the respective concave portion 16.
With reference to
In the variant shown in
In the further variant shown in
In use, during the rotation of the ring gear 6 at the normal running speed, a part of the lubricant oil is pushed, as a result of a centrifugal effect, towards the tubular portion 8B and into the chamber 26, from which it flows out through the passage/s 25 and enters the collection collector 11 through the passage 24, thus placing itself on the inside of the concave portion 14, as shown in
When the rotation speed of the ring gear 6 and, hence, of the ring gears 3 and 10 decreases, at least part of the oil mass contained in portion 14 falls, due to gravity, towards the ring gear 6, thus being collected in the concave portions 16.
Owing to the above, it is evident that, whatever the speed of rotation of the transmission, the drawn oil is always confined on the inside of the collection collector 11 and then returned, in a known manner, towards a collection area, from which it is reintroduced into the system, without significant leaks and without the risk for the drawn oil to come into contact with rotary parts of the transmission 1.
The embodiment shown in
In the transmission 30, the ring gear or the ring gears 10 are coupled to the frame 2 by means of a coupling element 31, which extends coaxial to the axis 5 and rotates around the axis 5 itself, preferably in a direction that is contrary to the direction of rotation of the coupling element 8 and corresponds to the direction of rotation of the ring gear 3.
The element 31 comprises a tubular portion 32, which extends between the collection collector 11 and the tubular body 8B coaxially to the axis 5. The tubular portion 32 has an internal diameter that is greater than the external diameter of the tubular body 8B and delimits an internal annular chamber 33, which is designed to house a lubricant liquid and communicates, on one side, with the passage 25 and, on the other side, with a passage 34, which, in turn, communicates with the passage 24. In this specific case, the chamber 26 is delimited by the tubular portion 8B and by the ring gear 6 and the passages 25 and 34 are axially not aligned.
Conveniently, the tubular portion 32 is made by means of two bodies axially arranged alongside, like the tubular portion 8B.
The particular way in which the collection collector 11 is designed, on the one hand, prevents the use of mechanical seals between the tubular portions 8B and 32 and the collection collector 11 and, on the other hand, makes it easier for the transmission to be assembled.
The embodiment shown in
In the transmission 40, the coupling element 8 is stably connected to the frame 2 so as to support the ring gear 6 in an axially and angularly fixed position relative to the frame 2 itself, whereas the coupling element 31 extends on the inside of the tubular portion 8B.
The transmission 40 comprises a collection collector 41, which differs from the collection collector 11 in that the two half-shells 12 are divided from each other along the radial plane 13, are moved apart from each other and from the plane 13, are arranged so as to project on opposite axial sides of the tubular portion 8B, and extend in positions facing the ring gear 6 and the ring gears 10, as shown in
In particular, each half-shell 12 has its own section 15 integrally connected to a respective axial end of the tubular portion 8B, so as to define, with part of the tubular portion 8B itself and of the ring gear 6, a respective concave portion 14.
According to a variant that is not shown herein, one section 15 or both sections 15 is or are directly or indirectly connected to the frame 2.
Each half-shell 12 has its own concave portion 16 facing the ring gears 10 and its own wall 18, which practically faces the toothing 7 and 9 of the external ring gear 6 and of the ring gears 10.
As a consequence, each concave portion 16 is arranged with its bottom wall 20 substantially parallel to the axis 5 or slightly inclined relative to the axis 5 itself and, in this specific case, alongside the axes 10A and with its wall 22 extending towards the toothing 7 of the external ring gear 6 and towards the ring gears 10. In this way, each one of the walls 22 delimits, with the axial surfaces of the ring gears 10, a respective radial inlet passage 42 to let the drawn oil into the relative half-shell 12.
Conveniently, the passage 42 is tapered in a radial direction towards the external ring gear 6, so as to help the drawn oil get into the relative half-shell 12 as a result of a centrifugal effect and so as to inhibit or obstacle the outflow of oil from the relative half-shell 12 as the speed of rotation of the coupling element 31 and of the ring gears 10 decreases.
The presence of the walls 22 avoids any contact between the drawn oil and the ring gears 10 or the coupling element 31 after the oil has entered the relative half-shell 12, whereas the walls 18 intercept the oil splashes flowing out of the toothing 7, 9, thus channelling them into one or the other concave portion 14, 16.
Owing to the above, it is evident that transmissions 1, 30 and 40 described herein can be subject to changes and variations, without for this reason going beyond the scope of protection set forth in the independent claims.
In particular, there can be a different number or different types of ring gears and the half-shells 12 defining the collection collector 11 could be different in terms of geometry and/or sizes, but they are always such as to collect and hold the mass of drawn oil, whatever the speed of rotation, and to avoid any kind of return of the mass of drawn oil towards the movable part of the transmission, as the speed of rotation varies.
Number | Date | Country | Kind |
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TO2014A000624 | Aug 2014 | IT | national |
Filing Document | Filing Date | Country | Kind |
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PCT/IB2015/055890 | 8/3/2015 | WO | 00 |