EP3052824A1

EP3052824A1 - Method of mechanical coupling between machine assemblies, and coupling obtained by this method

Info

Publication number: EP3052824A1
Application number: EP14796536.2A
Authority: EP
Inventors: Roel Verhoog; Alain BARRY; Maxime Miot
Original assignee: Valeo Embrayages SAS
Current assignee: Valeo Embrayages SAS
Priority date: 2013-10-03
Filing date: 2014-10-01
Publication date: 2016-08-10
Also published as: FR3011597A1; FR3011597B1; WO2015049463A1

Abstract

The method of mechanically coupling two parts (10, 12), a first (12) of the two parts being formed from a first conductive material and with a first contact area delimiting at least one recess (22) in the first part, a second (10) of the two parts being formed from a second conductive material incompatible with welding with the first conductive material and with a second contact area (16) forming at least one projection of the second part (10) having a dimensional interference with the first contact area (22), involves carrying out the following steps: first, bringing the two parts (10, 12) together in such a way that the first and second contact areas (16, 22) come at least partially into contact with each other; then fitting the second part (10) into the first part (12) by means of a relative movement parallel to an insertion axis while causing an electric current to flow between the two parts (10, 12) and sufficient heating by Joule effect to bring at least one of the first and second contact areas (16, 22) locally to a temperature greater than or equal to a melting temperature, causing a radial deformation of at least one of the first and second contact areas (16, 22).

Description

METHOD OF MECHANICAL COUPLING BETWEEN MACHINE ORGANS AND

COUPLING OBTAINED BY THIS PROCESS

TECHNICAL FIELD OF THE INVENTION

The invention relates to a coupling method for establishing a rigid connection, in particular between two rotating machine members or other moving parts of a machine. It relates in particular to a method for coupling between two parts incompatible with the weld, for example two metal parts, one of which is sintered or has been treated.

STATE OF THE PRIOR ART

It has been proposed in EP 1 941 964 Bl, to assemble two pieces between them, one of which before assembly a dimensional interference with a cavity formed in the other, by joint application of a pressure and a high intensity pulsed current obtained by a capacitor discharge, so as to achieve the area between the pieces a weld bead. This method implies, however, that the materials are compatible with each other at the weld, which excludes for example the use of this technique when one of the parts is sintered.

It has also been proposed in document EP 0 670 751 B1 to join together two pieces held face to face in rough contact, in the presence of a seizing promoter, for example a polysiloxane, by application. a relative lateral movement between the contact surfaces, which causes a transfer of material between the two surfaces and the formation of a seal, an electric current being applied during or after completion of the joint. This method, proposed for making joints between pieces of iron or ferrous alloy, and therefore between materials compatible with one another for a weld, requires preparation of the surfaces before assembly, and requires a seizing promoter. It also requires a pressure maintenance time between the parts for the realization of the seal, resulting in a manufacturing cycle time incompatible with high rates. Finally, it does not allow for making a seal having sufficient mechanical strength between two metal parts not compatible with the weld. SUMMARY OF THE INVENTION

The invention aims to overcome the disadvantages of the state of the art and to propose a method of coupling between machine members.

To do this is proposed, according to a first aspect of the invention, a method of mechanical coupling of two parts, a first of the two parts being formed of a first conductive material and with a first contact zone delimiting at least a cavity in the first piece, a second of the two pieces being formed of a second conductive material incompatible with the solder with the first conductive material and with a second contact area formed on a projecting portion of the second piece and having a dimensional interference with the first contact zone, the method of approaching the two parts of each other so that the first and second contact areas at least partially come into contact with one another, and then to pass from one of the two parts to the other by the first and the second contact zones an electric current of sufficient intensity for, by heating by Joule effect, making at least ductile at least part of at least one of the first and second contact areas and is simultaneously penetrating the projecting portion of the second piece in the cavity of the first piece by a relative movement between the first piece and the second piece parallel to an insertion axis by radially deforming at least the portion made at least ductile.

Thus, despite the incompatibility to the welding between the constituent materials of the two parts, a mechanical assembly with a high quality of contact.

Preferably, the passage of the current lasts at least during the entire relative movement of fitting, to make at least duct contact areas gradually coming into contact with each other during the movement.

Depending on the materials of the two parts, it may be preferable to continue the heating beyond the ductile state so that the passage of the current caused by Joule effect the merger of at least a part of a at least first and second contact zones, or even at least a local merger on the two contact zones.

According to a preferred embodiment, at least one of the contact areas is not a surface of revolution before deformation, which allows the coupling to transmit a high torque around the reference axis. In particular, it can be provided that at least one of the contact zones comprises a grooved surface, or provided with radial holes or with an elliptical cross section.

To facilitate the docking and the initial positioning of the two parts, it can be provided that at least one contact area is provided before fitting a centering chamfer.

Preferably, the passage of the electric current is pulse. It can in particular be caused by a capacitor discharge. The speed of the relative movement of penetration of the parts depends on the speed with which heating by Joule effect makes it possible to reach the desired state, ductile or melt, the dimensional interference part of at least one of the zones of contact. Thanks to a very intense current establishing itself very quickly as soon as the contact between the contact zones is effective, it is possible to obtain relatively high speeds of penetration, for example and purely indicative of the order of 0, 5m / s (10ms to bind 5mm of sheet metal).

According to one embodiment, one of the first and second materials is a sintered material.

Naturally, it is possible to include in the method, the prior forming steps of the first and second parts.

According to another aspect of the invention, it relates to a mechanical assembly consisting of a sintered hub coupled to a rotating member by the method according to any one of the preceding claims.

BRIEF DESCRIPTION OF THE FIGURES Other features and advantages of the invention will become apparent from reading the description which follows, with reference to the accompanying figures, which illustrate: Figure 1 isometric view of two parts of a first assembly in a position d prior approach to the implementation of the coupling method according to the invention; Figure 2 is a top view of the two parts of Figure 1, after coupling, Figure 3, a section of the two parts in the position of Figure 2; Figure 4, a detail of Figure 2, showing dimensional interference between the parts before coupling, and the resulting position after coupling; Figure 5, a section of two parts of a second assembly, in an approach position prior to the implementation of the method of the invention; - Figure 6, a section of the two parts of Figure 5, after coupling by the method of the invention; Figure 7 is a top view of the two parts of Figure 5, showing a dimensional interference between the parts before coupling, and the resulting position after coupling; - Figure 8, an isometric view of two parts of a third assembly, in a position of approach prior to the implementation of the method of the invention; Figure 9, a section of the two parts of Figure 8, after coupling by the method of the invention; - Figure 10, a top view of the two parts of Figure 8, showing a dimensional interference between the parts before coupling, and the resulting position after coupling; FIG. 11, an isometric view of two parts of a fourth assembly, in a position of approach prior to the implementation of the method of the invention; Figure 12, a section of the two parts of Figure 11, before coupling by the method of the invention; Figure 13, a section of the two parts of Figure 11, after coupling by the method of the invention; Figure 14 is a top view of the two parts of Figure 11, showing a dimensional interference between the parts before coupling, and the resulting position after coupling; FIG. 15, an isometric view of two parts of a fifth assembly, in a position of approach prior to the implementation of the method of the invention; Figure 16, a section of the two parts of Figure 15, after coupling by the method of the invention; Figure 17 is a top view of the two parts of Figure 15, showing a dimensional interference between the parts before coupling, and the resulting position after coupling; FIG. 18, an isometric view of two parts of a sixth assembly, in an approach position prior to the implementation of the method of the invention; Figure 19, a section of the two parts of Figure 18, before coupling by the method of the invention; Figure 20, a section of the two parts of Figure 18, after coupling by the method of the invention; Figure 21 is a top view of the two parts of Figure 18; Figure 22, a detail of Figure 21, showing dimensional interference between the parts before coupling, and the resulting position after coupling.

For clarity, identical or similar elements are identified by identical reference signs throughout the figures.

DETAILED DESCRIPTION OF EMBODIMENTS

Figures 1 to 4 is illustrated a first implementation of the method according to the invention for the coupling of two parts, in this case a hub 10 made of sintered material and a metal clutch web 12. The hub has an internal groove 14 for its fitting on a shaft and, at its outer periphery, a surface 16 forming a ring gear having teeth 17. An outer diameter 18 of the ring is defined, which is the diameter of the cylinder tangent to the teeth and containing the entire hub 10, and a bottom diameter of teeth 20, which is the diameter of the smallest cylinder tangent to the toothing 16. The disc has meanwhile a circular central opening 22. In the position of FIG. 1 before coupling, the diameter 24 of the opening 22 of the disc is smaller than the outer diameter 18 of the ring gear 16 and greater than the diameter of the toothing base 20. To form a mechanical coupling e positive between the hub 10 and the disk 12, approaching the two parts 10, 12 of one another so that the teeth 17 come into contact with the periphery of the circular central opening 22 of the disc 12 A current of very high intensity is then applied by discharging a capacitor 26 into an electrical circuit 28 which passes through the two parts 10, 12 passing through the contact zone between the teeth 17 and the central opening 22 while forcing the penetration the hub 10 in the opening 12 by translation without rotation. The contact zone undergoes a very rapid Joule heating, which is sufficient to locally bring the contact areas to a melting temperature, causing the teeth 17 to sag and dig into the corresponding groove opening. FIG. 4 shows in fine dotted lines the initial profiles of a tooth and the opening and in continuous lines the final profile of the contact zone. In the contact zone, an intimate nesting of the two parts is thus obtained, similar to a splined connection. Outside the contact areas, the circular central opening 22 and the recesses between the teeth 17 have not melt and have not been deformed. Despite the incompatibility with the welding between the sintered hub and the metallic web, and consequently the absence of solder rod, the coupling produced is able to transmit high torsion torques, because of the interlocking of the shapes in the areas of deformed contact.

FIGS. 5 to 7 illustrate a second application of the method for making a coupling between two parts 10, 12, one of which, in the female series 12, has an opening 22 with an elliptical profile, and Another, male, is a solid piece 10 having a convex outer surface 16 of equally elliptical profile, with slight interference before mating. In the position of Figure 5, the two parts are brought closer to one another until contact is obtained. To facilitate the centering in this transient position, there is provided in one of the parts, here the female part 12 a chamfer 30 to guide the other part 10. It is then passed a high intensity pulsed electric current through the two pieces, from an electric capacitor 26 previously loaded, to obtain a local melting of the contact areas 16, 22 of the two parts, while interpenetrating the two parts 10, 12 in relative translation movement. As the male piece penetrates into the female piece, the local melting of the contact areas continues. The penetration time is set to substantially coincide with the discharge time of the capacitor, so that the merging between contact zones propagates during the penetration in the direction of the latter.

In the example illustrated in Figures 8 to 10, the above method has been adapted to the coupling of a cylindrical male part 10 in a corresponding cavity 22 of a female part 12 of generally annular shape. The female part 12 is provided with lateral cavities 32 constituted by holes opening radially into the central cavity 22. Before coupling, the outside diameter of the contact zone 16 the male part 10 is very slightly greater than the inside diameter of the central cavity 22 of the female part 12, this dimensional interference preventing a cold fitting. The male part 10 is provided with a centering chamfer 30, allowing a controlled docking of the two parts. As before, a high intensity electric current is passed from one room to the other through the contact interface, while at the same time imposing penetration of the male part into the female part by axial translational movement. contact between melt and deform to allow penetration. During penetration, the parts of the contact zone 16 of the male part 10 which are melted and then found opposite one of the lateral cavities flow very slightly into the lateral cavities by viscoelastic deformation, before cooling forming a protuberance 36. A positive coupling is thus obtained in these zones, which subsequently allows the transmission of torsion torques. It should be noted that the shape of the parts makes it possible alternatively to envisage a penetration movement combining a translation in the axis of the parts and a rotation about this axis, for example a helical movement.

In the example illustrated in FIGS. 11 to 14, coupling is also carried out between a male part 10 having a substantially cylindrical contact zone 16 and an annular female piece 12 having a cylindrical central cavity 22. in the male part of the lateral cavities 32 opening on the cylindrical contact surface 16. As previously, the male part 10 is also provided with a chamfer 30 facilitating the centering with the female part 12 at the docking. By simultaneously applying a high intensity current and a translational movement, penetration of the male part 10 into the female part 12, and a viscoelastic flow of the molten material of the female part 12 into the lateral cavities 32 of the male piece 10, so as to form protuberances 36 which subsequently, after cooling of the coupling, provide a positive coupling indémontable between the parts 10, 12, allowing the transmission of force and torque. It should be noted that the shape of the parts makes it possible alternatively to envisage a penetration movement combining a translation in the axis of the parts and a rotation about this axis, for example a helical movement.

A variant of the previous examples is illustrated in Figures 15 to 17. It is again to achieve a positive coupling between a cylindrical male part 10 and a female part 12 having an opening also cylindrical 22, whose diameter, before coupling, is slightly greater than that of the male part 10. It is provided for this purpose in the female part axial peripheral grooves 32, intended to allow local viscoelastic flow of the molten material of the zone contact 16 of the male part 10 and the formation of local protuberances of the male part 10, penetrating into the grooves 32. In this embodiment, the penetration can advantageously be effected by a movement combining a translation in the axis of parts and a slight rotation, for example a helical movement, so as to ensure that the parts of the male piece coming opposite the lateral cavities of the female part at the end of the penetration operation have been at a certain moment during the penetration in direct contact of the female part and were thereby heated by the Joule effect.

In the example of Figures 19 to 22, it seeks to couple a male part 10 having three cylindrical pins 38 defining three cylindrical contact zones 16 on a female part 12 having three openings 22 or corresponding cavities. Initially, the pins 38 have a diameter slightly greater than that of the openings 22. After docking, a current of high intensity is applied so as to cause a melting in the contact zones 16, 22 between the two parts, while forcing the penetration pions 38 in the openings, with viscoelastic deformation of the contact areas 16, 22. After cooling, the distribution of the pins 38 ensures a perfect transmission of the torsional moments around the axis of penetration.

In all embodiments, the materials used are incompatible with the weld. Positive interlocking coupling is achieved without a solder ring. Depending on the materials chosen, it can be expected that only one of the parts locally reaches its melting temperature, or that it is reached for both parts.

Various variants are possible. A variant of the example of FIGS. 18 to 22 consists of distributing pawns 38 and cavities 22 on each of the pieces. It is also conceivable to combine characteristics of the various examples with one another, to make others, for example combining the lateral cavities 32 of a male part 10 according to FIGS. 11 to 14 with lateral cavities 32 of a female part 12 according to Figures 8 to 10, angularly offset from the previous. Depending on the shape of the parts to be coupled, one can choose to move one or the other or both parts, to achieve the desired relative movement of fit. The high intensity current can be generated by any suitable means.

Claims

A process for mechanical coupling of two parts (10, 12), a first (12) of the two parts being formed of a first conductive material and with a first contact zone delimiting at least one cavity (22) in the first part, a second (10) of the two pieces being formed of a second conductive material incompatible with the solder with the first conductive material and with a second contact area (16) formed on a projecting portion of the second piece and having a dimensional interference with the first contact area (22), characterized in that:

the two parts (10, 12) are brought closer to one another so that the first and second contact areas (16, 22) at least partly come into contact with one another,

one of the two pieces (10, 12) is passed from one of the two pieces (10, 12) to the other by the first and second contact areas (16, 22) of sufficient intensity to, by Joule heating, render at least ductile at least a portion of at least one of the first and second contact areas (16, 22) and is simultaneously penetrating the projecting portion of the second piece in the cavity (22) of the first piece by a relative movement between the first piece (12) and the second piece (10) parallel to an insertion axis by deforming radially at least the at least ductile portion.

Coupling method according to claim 1, characterized in that the passage of the current lasts during the entire relative movement of fitting.

Coupling method according to any one of the preceding claims, characterized in that the passage of the current causes the melting of at least a part of at least one of the first and second contact areas (16, 22).

4. Coupling method according to any one of the preceding claims, characterized in that at least one of the first and second contact areas (16, 22) comprises a surface parallel to the axis of insertion.

5. Coupling method according to any one of the preceding claims, characterized in that at least one of the contact areas (16, 22) is not a surface of revolution before deformation.

Coupling method according to one of the preceding claims, characterized in that at least one of the first and second contact areas (16, 22) is provided with a centering chamfer (30).

7. Method according to any one of the preceding claims, characterized in that the passage of the electric current is pulse.

8. Method according to the preceding claim, characterized in that the passage of the electric current is caused by a capacitor discharge (26).

9. Coupling method according to any one of the preceding claims, characterized in that one of the first and second materials is a sintered material.

Mechanical assembly consisting of a sintered hub coupled to a rotating member by the method according to any one of the preceding claims.