FR3133171A1 - motion transmission device for an aircraft - Google Patents

Abstract

The subject of the invention is a movement transmission device (10) for an actuation and/or opening and/or closing and/or locking and/or unlocking mechanism of a door or a valve of a mechanical movement control device of an aircraft, comprising a transmission shaft (20) extending along a longitudinal axis (A). The transmission shaft (20) comprises at least one fixing section (22). The motion transmission device (10) further comprises a transmission element (40) fixed to the fixing section (22). The fixing section (22) is of non-circular section in a plane orthogonal to the longitudinal axis (A) and comprises at least one fixing surface (24). The transmission element (40) comprises a complementary fixing surface (42) matching the flat fixing surface (24). . Figure for abstract: Fig. 9

Description

motion transmission device for an aircraft

The present invention relates to the field of motion transmission devices, and particularly to the field of transmission devices comprising a transmission shaft and one or more transmission elements arranged on the shaft.

Such transmission devices are generally used for actuation, that is to say the opening, closing, locking and/or unlocking of a mechanical control device of an aircraft such as a door, a valve, an angle gear or a flight control of an aircraft such as an airplane.

The transmission elements arranged on the shaft can consist of bearings often made by the presence of bearings, lever arms making it possible to transform the rotation of the shaft into circular movement of the end of the levers, pinions, cams or any other type of transmission elements.

The transmission shafts of such known transmission devices are for the most part guided in rotation and serve to transmit movements via the transmission elements, also called accessories.

The transmission shafts of such known transmission devices are for the most part metallic and tubular in shape, the accessories or transmission elements are generally secured by a cylindrical adjustment associated with radial pinning allowing locking in rotation around a longitudinal axis of the transmission shaft and relative translation in direction parallel to the longitudinal axis. Double pinning most of the time ensures redundancy of the fixing. Such a transmission device is for example known from document EP 0 743 240 B1.

• la présence des goupilles demande un perçage radial de l’arbre de transmission, ce qui réduit d’autant la section résistante de l’arbre de transmission tout en présentant un accident de forme propre à concentrer des contraintes dans cette zone lors de la sollicitation de l’arbre ;
• la transmission, des actions mécaniques se faisant via les goupilles concentre les efforts des goupilles sur l’arbre de transmission dans la zone déjà la plus chargée par la torsion de l’arbre de transmission ;
• cette concentration des problématiques de résistance dans les zones de goupillage de l’arbre de transmission conduit à un surdimensionnement des pièces mécaniques et donc à une masse de l’ensemble du dispositif de transmission monté non optimale.

Such a known transmission device has in particular the following drawbacks:

• the presence of the pins requires radial drilling of the transmission shaft, which reduces the resistant section of the transmission shaft while presenting an accident of shape capable of concentrating stresses in this zone during the loading of the tree ;
• the transmission, mechanical actions taking place via the pins concentrate the efforts of the pins on the transmission shaft in the zone already most loaded by the twisting of the transmission shaft;
• this concentration of resistance problems in the pinning zones of the transmission shaft leads to an oversizing of the mechanical parts and therefore to a non-optimal mass of the entire mounted transmission device.

One way to avoid or reduce the extent of these drawbacks could consist of transmitting mechanical actions via splines or producing integral shafts on which the accessories are formed in one piece by machining or by 3D metal printing by example.

This solution nevertheless has the disadvantage of making detachment or replacement of accessories difficult or impossible.

It is an object of this application to propose a transmission device allowing easy detachment and replacement of transmission elements or accessories. It is also an object of the present application to propose a transmission device that is light in weight, inexpensive in production and avoids areas of concentration of mechanical stresses in a transmission shaft of the transmission device.

To this end, the present invention relates to a movement transmission device for an actuation and/or opening and/or closing and/or locking and/or unlocking mechanism of a mechanical movement control device. such as a door, a valve, an angle gear or a flight control of an aircraft. The transmission device includes a transmission shaft extending along a longitudinal axis. The transmission shaft has at least one fixing section. The transmission device further comprises a transmission element fixed to the fixing section. The fixing section has a non-circular cross section in a plane orthogonal to the longitudinal axis and comprises at least one fixing surface. The transmission element further comprises a complementary fixing surface matching the fixing surface.

According to one possibility, the fixing surface and the complementary fixing surface are essentially flat and each extend in a plane parallel to the longitudinal axis.

According to a possible additional characteristic, the transmission shaft is made of a composite material, preferably of a composite material comprising carbon fibers.

These characteristics make it possible to obtain a transmission device which is of reduced weight and sufficiently rigid.

According to one possibility, the transmission element is made of a metallic material, preferably aluminum.

In accordance with a preferred embodiment, the fixing section comprises in a plane orthogonal to the longitudinal axis a cross section of essentially polygonal shape, preferably of the shape of an equilateral and/or equiangular polygon.

These characteristics allow an easy and rigid connection between the transmission element and the transmission shaft.

According to a possible additional characteristic, the transmission shaft is a tubular element.

These characteristics make it possible to obtain a transmission device which is of reduced weight and sufficiently rigid.

According to a possible additional characteristic, the transmission element comprises a fitting part fitted onto the fixing section and a tightening screw making it possible to tighten the fitting part against the fixing section.

According to one possibility, the transmission element comprises a pin forming a mechanical obstacle to movement of the transmission element along the transmission shaft in parallel to the longitudinal axis.

According to a preferred embodiment, the transmission element and/or the transmission shaft each comprise a bore in which the pin is received, the bore of the transmission element being preferably arranged in the part d the fitting and/or the drilling of the transmission shaft being preferably arranged in the fixing surface.

These characteristics make it possible to block the transmission element against a translational movement of the transmission element along the longitudinal axis of the transmission shaft.

According to a possible additional characteristic, the transmission device further comprises an adhesive connecting the transmission element to the fixing section.

The invention also relates to an aircraft, preferably an aircraft comprising a transmission device according to the invention.

The invention will be better understood, thanks to the description below, which relates to two preferred embodiments, given by way of non-limiting example, and explained with reference to the appended schematic drawings, in which:

is a schematic representation of a transmission shaft of a transmission device according to a first preferred embodiment of the invention;

is a schematic representation of a mold allowing the manufacture of the transmission shaft of the transmission device according to the first preferred embodiment of the invention;

is a sectional view of the mold allowing the manufacture of the transmission shaft of the transmission device according to the first preferred embodiment of the invention;

is a schematic representation of a transmission element of a transmission device according to the first preferred embodiment of the invention;

is a schematic representation of the transmission device according to the first preferred embodiment of the invention;

is a sectional view of the transmission device according to the first preferred embodiment of the invention;

is a sectional view of the transmission device according to the first preferred embodiment of the invention;

is a schematic representation of the transmission element of the transmission device according to the first preferred embodiment of the invention;

is a perspective view of the transmission device according to the first preferred embodiment of the invention;

is a sectional view of the transmission device according to the first preferred embodiment of the invention;

is a sectional view of the transmission device according to the first preferred embodiment of the invention;

is a perspective view of a sheet metal holding the transmission element of the transmission device according to the first preferred embodiment of the invention;

is a schematic representation of a variant of the transmission element of a transmission device according to the preferred embodiment of the invention;

is a sectional view of the transmission device according to a second preferred embodiment of the invention.

The present application relates to a movement transmission device 10 for an actuation and/or opening and/or closing and/or locking and/or unlocking mechanism of a mechanical movement control device such as a door, a valve, a corner gear or a flight control of an aircraft. The present application also relates to an aircraft comprising a mechanism for actuating and/or opening and/or closing and/or locking and/or unlocking a mechanical movement control device such as a door. , a valve, an angle gear or a flight control provided with such a movement transmission device 10. The movement transmission device 10 comprises a transmission shaft 20 extending along a longitudinal axis A The transmission shaft 20 comprises at least one fixing section 22. The movement transmission device 10 further comprises a transmission element 40 fixed to the fixing section 22. The fixing section 22 is of non-circular cross section in a plane orthogonal to the longitudinal axis A and comprises a fixing surface 24. The transmission element 40 comprises a complementary fixing surface 42 matching the fixing surface 24.

The fixing surface 24 as well as the complementary fixing surface 42 matching the fixing surface 24 prevent relative rotation around the longitudinal axis A between the transmission element 40 and the transmission shaft 20. The transmission element 40 is held on the fixing section 22 by shape conjugation.

According to one possibility, the fixing surface 24 and the complementary fixing surface 42 can be essentially flat and each extend in a plane parallel to the longitudinal axis A.

Alternatively, the fixing surface 24 and the complementary fixing surface 42 can be of curvilinear shape, preferably having a cross section in a plane orthogonal to the longitudinal axis A in the shape of an arc of a circle, the center of which is distant from the longitudinal axis A, that is to say whose center is not coincident with the longitudinal axis A.

The transmission elements 40 can consist of bearings often made by the presence of bearings, lever arms making it possible to transform the rotation of the transmission shaft 20 into circular movement of the end of the levers, pinions, cams or any other type of transmission elements. There discloses a motion transmission device 10 provided with a transmission element 40 made in the form of a bearing.

The transmission elements 40 can be adapted for fixing sections 22 arranged on a central part 23 of the transmission shaft 20 or can be adapted for fixing sections 22 arranged on an end part 25 of the transmission shaft. transmission 20. The transmission elements 40 intended to be fixed to fixing sections 22 arranged on the end part 25 of the transmission shaft 20 may have a bearing surface 43 which can rest against an end face 27 of the transmission shaft 20 present on the end part 25 of the transmission shaft 20. The bearing surface 43 and the end face 27 thus form a bearing preventing movement of the transmission element 40 on the transmission shaft 20 along the longitudinal axis A. The discloses such a transmission element 40 intended to be fixed to a fixing section 22 arranged on the end part 25 of the transmission shaft 20.

The transmission shaft 20 can be manufactured from a composite material, preferably from a composite material comprising carbon fibers.

Alternatively, the transmission shaft 20 can be made of a metallic material, in particular for applications where the weight of the transmission shaft 20 is not decisive.

The transmission element 40 can be made of a metallic material, preferably aluminum.

The fixing section 22 may comprise in a plane orthogonal to the longitudinal axis A a cross section of essentially polygonal shape, preferably of the shape of an equilateral and/or equiangular polygon.

In the first preferred embodiment of the invention, as disclosed in Figures 1 to 3, 5 to 7 and 9 to 11 for example, the fixing section 22 may comprise a section in the shape of an equilateral and equiangular hexagon.

In the second preferred embodiment of the invention, as disclosed in the , the fixing section 22 may have a section shaped like an ellipse.

The transmission shaft 20 may be a tubular element provided with a hollow 21. The hollow 21 may comprise in a plane orthogonal to the longitudinal axis A a cross section of essentially polygonal shape, preferably of the shape of an equilateral polygon and/or equiangular. According to a preferred variant of the invention, the hollow 21 may have the shape of the same polygon that the fixing section 22 takes.

According to an alternative, the hollow 21 may comprise in a plane orthogonal to the longitudinal axis A a cross section of essentially round shape.

The transmission shaft 20 and/or the hollow 21 may/can comprise a constant section over their entire length in a plane orthogonal to the longitudinal axis A. In this case, a single fixing section 22 continuous over the entire length of the transmission shaft 20 or a series of several consecutive fixing sections 22 along the length of the transmission shaft 20 can/can be formed.

The transmission element 40 may comprise a fitting part 44 fitted onto the fixing section 22 and a tightening screw 46 making it possible to tighten the fitting part 44 against the fixing section 22. The complementary fixing surface 42 can be provided on the fitting part 44.

This assembly makes it possible to prestress the fitting part 44 to fix the transmission element 40 to the fixing section 22 by friction between the fixing surface 24 and the complementary fixing surface 42.

The fitting part 44 may have a plurality of complementary fixing surfaces 42, preferably non-parallel to each other. The number of complementary fixing surfaces 42 is preferably equal to the number of flat fixing surfaces 24 provided on the fixing section 22 of the transmission shaft 20. The fitting part 44 can in cross section have the shape of the same polygon that the fixing section 22 takes.

The transmission shaft 20 may have edge fillets on its external surface in order to limit the areas of potential stress concentration on the transmission shaft 20.

The transmission element 40 may comprise a pin 48 forming a mechanical obstacle to movement of the transmission element 40 along the transmission shaft 20 in parallel to the longitudinal axis A.

The transmission element 40 and/or the transmission shaft 20 may each comprise a bore 50, 26 in which the pin 48 is received, the bore 50 of the transmission element 40 being preferably arranged in the fitting part 44 and/or the bore 26 of the transmission shaft 20 being preferably arranged in the fixing surface 24.

The pin 48 can be held in the holes 50, 26 using a retaining plate 54. The retaining plate 54 can be provided with an opening receiving the pin 48. The retaining plate 54 can be fixed to the transmission element 40, preferably to the fitting part 44 of the transmission element 40 using a fixing screw 56 screwed into a tapped hole 58 of the transmission element 40.

The movement transmission device 10 may also include an adhesive 60 connecting the transmission element 40 to the fixing section 22.

The transmission element 40 can include a hole 52 for injecting the adhesive 60. The hole 52 can open into the complementary fixing surface 42. The hole 52 can be arranged in the fitting part 44.

The fixing section 22 of polygonal shape allows a multiplication of the stress zones in the transmission shaft 20, which promotes the progressiveness of the local loading between the transmission shaft 20 and the transmission element 40.

With regard to a twist of the transmission shaft 20, the polar inertia of cross section of the fixing section 22 corresponds to the accumulation of the polar inertias of the transmission shaft 20 and of the transmission element 40. From this fact, the torsional rigidity of the fixing section 22 is greater and the shear stress due to torsion is lower. With regard to bending of the transmission shaft 20, the cross-section inertias accumulate in the same way and therefore have the same beneficial effect. This property makes it possible to envisage pinning in the fixing surface 42, preferably in a central part of the fixing surface 42, without the pinning generating additional stresses, the tightening of the transmission element 40 reinforces this central part of the fixing surface 42. This pinning in no way reduces the performance of the transmission device 10 unlike a conventional transmission device where it represents the weak point of the device.

• mise à disposition d’une préforme d’un arbre de transmission 20 et mise à disposition d’un élément de transmission 40 comportant une surface de fixation 42 complémentaire essentiellement plane ;
• agencement de l’élément de transmission 40 par rapport à la préforme de sorte à positionner la surface de fixation 42 complémentaire en face d’une partie de la préforme destinée à former d’un tronçon de fixation 22 ;
• insertion de l’agencement de l’élément de transmission 40 et de la préforme dans un moule 100 ; et
• injection d’une matrice dans le moule 100 pour former l’arbre de transmission 20 comportant un tronçon de fixation 22 pourvu d’une surface de fixation 24 essentiellement plane venant épouser la surface de fixation complémentaire 42 de l’élément de transmission 40.

The motion transmission device 10 according to the present application can be manufactured using a manufacturing process comprising the following successive steps:

• provision of a preform of a transmission shaft 20 and provision of a transmission element 40 comprising an essentially flat complementary fixing surface 42;
• arrangement of the transmission element 40 relative to the preform so as to position the complementary fixing surface 42 opposite a part of the preform intended to form a fixing section 22;
• inserting the arrangement of the transmission element 40 and the preform into a mold 100; And
• injection of a die into the mold 100 to form the transmission shaft 20 comprising a fixing section 22 provided with an essentially flat fixing surface 24 which matches the complementary fixing surface 42 of the transmission element 40.

• mise à disposition d’une préforme d’un arbre de transmission 20 ;
• insertion de la préforme dans un moule 100 ;
• injection d’une matrice dans le moule 100 pour former l’arbre de transmission 20 comportant un tronçon de fixation 22 pourvu d’une surface de fixation 24 essentiellement plane ; et
• emmanchement d’une partie d’emmanchement 44 d’un élément de transmission 40 de sorte à ce qu’une surface de fixation complémentaire 42 de l’élément élément de transmission 40 vienne épouser la surface de fixation 24 de l’arbre de transmission 20.

Alternatively, the motion transmission device 10 according to the present application can be manufactured using a manufacturing process comprising the following successive steps:

• provision of a preform of a transmission shaft 20;
• insertion of the preform into a mold 100;
• injection of a die into the mold 100 to form the transmission shaft 20 comprising a fixing section 22 provided with an essentially flat fixing surface 24; And
• fitting of a fitting part 44 of a transmission element 40 so that a complementary fixing surface 42 of the transmission element element 40 comes to marry the fixing surface 24 of the transmission shaft 20 .

According to one possibility, the transmission shaft 20 can be manufactured by pultrusion, particularly in the case where the transmission shaft 20 has a constant section over its entire length.

The manufacturing process may include tightening a tightening screw 46 in order to tighten the fitting part 44 against the fixing section 22. Tightening the fitting part 44 against the fixing section 22 can advantageously make use of a deformability of the transmission element 40.

The manufacturing method may include the application of an adhesive 60 between the transmission element 40 and the fixing section 22 to connect the transmission element 40 to the fixing section 22. The application of the adhesive 60 may be carried out by injecting the adhesive 60 into the hole 52.

The mold 100 may comprise two mold parts 110, 120. In the case where the transmission shaft 20 is made of composite material, the transmission shaft 20 can be molded in a female mold 100, polymerized under internal pressure via a inflatable bladder 130. This embodiment makes it possible to guarantee high quality of the external surface of the transmission shaft 20, which makes it possible to obtain at least one fixing surface 24 necessary for fixing the transmission element 40 precisely.

The method of manufacturing the motion transmission device 10 according to the present application may comprise a molding process corresponding to the molding process defined by patent application FR3109746A1.

Claims (11)

Movement transmission device for an actuation and/or opening and/or closing and/or locking and/or unlocking mechanism of a mechanical movement control device such as a door, a flap, an angle gear or a flight control of an aircraft, comprising a transmission shaft (20) extending along a longitudinal axis (A), the transmission shaft (20) comprising at least one section fixing section (22), the movement transmission device (10) further comprising a transmission element (40) fixed to the fixing section (22), characterized in that the fixing section (22) has a cross section not -circular in a plane orthogonal to the longitudinal axis (A) and comprises at least one fixing surface (24) and in that the transmission element (40) comprises a complementary fixing surface (42) matching the surface of fixing (24). Transmission device according to claim 1, characterized in that the fixing surface (24) and the complementary fixing surface (42) are essentially flat and each extend in a plane parallel to the longitudinal axis (A). Transmission device according to any one of claims 1 or 2, characterized in that the transmission shaft (20) is made of a composite material, preferably of a composite material comprising carbon fibers. Transmission device according to any one of claims 1 to 3, characterized in that the transmission element (40) is made of a metallic material, preferably aluminum. Transmission device according to any one of claims 1 to 4, characterized in that the fixing section (22) comprises in a plane orthogonal to the longitudinal axis (A) a cross section of essentially polygonal shape, preferably of shape of an equilateral and/or equiangular polygon. Transmission device according to any one of Claims 1 to 5, characterized in that the transmission shaft (20) is a tubular element. Transmission device according to any one of claims 1 to 6, characterized in that the transmission element (40) comprises a fitting part (44) fitted onto the fixing section (22) and a tightening screw ( 46) allowing the fitting part (44) to be tightened against the fixing section (22). Transmission device according to any one of claims 1 to 7, characterized in that the transmission element (40) comprises a pin (48) forming a mechanical obstacle to movement of the transmission element (40) along of the transmission shaft (20) parallel to the longitudinal axis (A). Transmission device according to claim 8, characterized in that the transmission element (40) and/or the transmission shaft (20) each have a bore (50, 26) in which the pin (48) is received ), the bore (50) of the transmission element (40) being preferably arranged in the fitting part (44) and/or the bore (26) of the transmission shaft (20) being preferably arranged in the fixing surface (24). Transmission device according to any one of claims 1 to 9, characterized in that it further comprises an adhesive (60) connecting the transmission element (40) to the fixing section (22). Aircraft comprising a motion transmission device (10) according to any one of claims 1 to 10.