FR2880395A1 - DEVICE FOR MECHANICAL COUPLING BETWEEN TWO ELEMENTS - Google Patents

Abstract

Coupling device 22 between a driving element intended to drive a driven element in rotation, the driven element being mounted on the driving element by means of a bearing comprising two concentric rings 24, 25 between which is arranged at least one row of d rolling elements 26 in contact with raceways formed on said rings, the passage of torque between the driving element and the driven element being effected by mechanical coupling with an annular friction element ensuring the passage of a couple calibrated limited to a predefined value between the driving element and the driven element, said friction element cooperating with an annular bearing surface of the driving element and having a diameter less than or equal to the outside diameter of said bearing.

Description

Mechanical coupling device between two elements.

  The present invention relates to the field of mechanical couplings used to transmit a torque between a driving element and a driven element. This type of device is used for example in the case of cooling fans of motor vehicle alternators. However, we seek more and more, for reasons of comfort, to reduce the noise of all origins in engines and their accessories.

  A cooling fan of the engine alternator is generally rotated by the alternator shaft, itself driven by a pulley cooperating with a drive belt. The rotational speed of the alternator shaft is directly proportional to the rotational speed of the motor. As a result, if the fan rotor is rigidly coupled to the alternator shaft, the aerodynamic noise generated by the fan becomes extremely important at high rotational speeds. On the other hand, the air flow of the high speed fan is often too high compared to the flow required to ensure efficient cooling. This results in a significant waste of energy.

  Some mechanical coupling devices between the fan and the fan drive member allow, beyond a certain speed of rotation of the driving part connected to the motor, to partially decouple the fan, so that the speed of rotation of the fan fan is limited, while the rotation speed of the driving part continues to grow. Such partial fan decoupling occurs when the aerodynamic drag torque of the fan becomes greater than the mechanical drive torque between the drive member and the fan. There is then a relative rotation between the fan and the alternator shaft, which allows the engine to run at high speed without the fan turns too fast and produce too much aerodynamic noise. Such devices are known in particular from documents US 4,437,846 and DE 28 22 638. The main disadvantage of these devices lies in their size and in the large number of elements to be assembled by the manufacturer of the alternator on the rotor and on the fan, which is detrimental in terms of cost and production time.

  The invention proposes to remedy these drawbacks.

  The invention provides a compact mechanical coupling device, simple structure, whose production can be easily automated and reasonable cost.

  The coupling device between a driving element and a driven element is intended to rotate the driven element, mounted on the driving element by means of a bearing. The bearing comprises two concentric rings between which is disposed at least one row of rolling elements in contact with the raceways formed on said rings. The passage of the torque between the driving element and the driven element is effected by mechanical coupling. The bearing comprises an annular friction element ensuring the passage of a calibrated torque limited to a predefined value between the driving element and the driven element, said friction element cooperating with an annular bearing surface of the driving element and having a diameter less than or equal to the outside diameter of said bearing.

  The annular friction element is thus very compact.

  Advantageously, the friction element is in the form of a seal. The same element thus provides the friction function and the sealing function.

  In one embodiment, the friction element is supported by one of the bearing races and is in frictional contact with the other race of the bearing.

  In one embodiment, the device comprises two friction elements disposed inside the bearing.

  Alternatively, the friction element is integral with the driven element and comes into frictional contact with an annular bearing surface of the driving element. The friction element may be integral with the inner ring of the bearing. The friction element may be in frictional contact with a bearing of the rotating race of another bearing.

  In one embodiment, one of the rings of the bearing is mounted on a non-rotating support. Said non-rotating support may comprise the non-rotating ring of another bearing.

  In one embodiment, the coupling member is supported by the driven member and is in frictional contact with a ring belonging to the driving member.

  A fan may comprise a hub provided with blades and a coupling device as described above fixed on said means. The outer ring of the bearing can be fitted into a bore of the wheel provided with blades.

  An alternator may comprise a rotating part, a non-rotating part and a fan mounted via said coupling device on said rotating part.

  Such a rolling bearing can be applied to any type of mechanical member, in which it is desired to transmit a torque and a rotational movement between a driving element and a driven element, with a possible speed differential between the two elements and a possible speed limitation of the driven element. This is ensured in a simple and particularly compact way with said rolling bearing.

  The present invention will be better understood on reading the detailed description of some embodiments taken by way of non-limiting examples and illustrated by the accompanying drawings, in which: FIG. 1 is an axial sectional view of a part of FIG. an alternator; FIG. 2 is a detail view of FIG. 1; FIGS. 3 to 6 are views in axial section of different embodiments of the rolling bearing; and FIG. 7 is a curve of the fan speed as a function of the speed of the alternator.

  As can be seen in FIG. 1, the alternator 1, of which only one end portion is shown, comprises a rotating part 2 and a non-rotating part 3. The rotating part 2 comprises a shaft 4, a non-visible rotor in the drawing and a grooved pulley 6 in which passes a drive belt 7 provided to be driven by a driving pulley secured to the crankshaft with thermal engine not shown. A spacer 5 mounted on the shaft 4 ensures the precise axial positioning of the rotor relative to the bearings that support it. The non-rotating part 3 comprises a casing 8, for example made of light alloy.

  Between the shaft 4 and the casing 8, is disposed a rolling bearing 9, of conventional type, provided with a rotating inner ring 10 whose bore is fitted with clamping on the shaft 4, an outer ring no rotating 11 whose cylindrical outer surface is fitted into a cylindrical bore of the casing 8, a row of rolling elements 12, here balls, arranged between the races of the inner and outer rings 10, a cage 13 maintaining the circumferential spacing of the rolling elements 12, here made of sheet metal, and two seals 14 and 15 mounted in annular grooves of the outer ring 11 and rubbing by flexible lips on an outer cylindrical bearing surface of the inner ring 10. The seals 14 and 15 are symmetrical with respect to a radial plane passing through the center of the rolling elements 12 and are provided with a frame covered with a soft material e, for example an elastomer. The races of the inner and outer rings 11 are formed by machining with chip removal to give them the desired depth. The outer ring 11 is held axially relative to the casing 8, in one direction by a radially inwardly projecting bead 16 forming part of the casing 8, and in the other direction by a flange 17 fixed to the casing 8 by means such as screws (not shown).

  The rotating part 2 further comprises a fan 18 in the form of a ring of blades 19 extending outwards and inclined substantially helically, and an annular hub supporting the blades 19. The hub 20 comprises a portion annular axial small diameter 21 provided with a bore. A coupling device 22 is arranged radially between the shaft 4 and the axial portion 21 of the central portion 20 of the fan 18 and axially between the spacer 5 and an annular spacer washer 23 in contact with a front radial surface of the inner ring. 10 of the bearing 9. Axial clamping can be ensured.

  As best seen in Figure 2, the coupling device 22 is in the form of a rolling bearing provided with an inner ring 24, an outer ring 25, a row of rolling elements 26 , here balls, a cage 27 for maintaining the circumferential spacing of the rolling elements 26 and coupling seals 28 and 29. The inner and outer rings 24 24 have raceways in the form of a deep groove for the rolling elements 26 and are provided with radial front surfaces. The bore of the inner ring 24 is fitted on the shaft 4 and in contact on one side with the spacer 5 and on the opposite side with the spacer washer 23. The inner ring 24 has an outer surface in the form of a cylindrical bearing, on one side and the other of the raceway. The outer ring 25 has an axial outer surface fitted into the axial portion 21 of the central portion 20 of the fan 18. The radial front surfaces of the outer ring 25 are aligned on the radial end surfaces of the inner ring 24. The outer ring 25 has a cylindrical bore, on both sides of the raceway. The cage 27 comprises a bead disposed on one side of the rolling elements, while the coupling seals 28 and 29 are arranged on the opposite side.

  The coupling joints 28 and 29 are identical, each comprising an armature 30 and a flexible portion 31. The armature 30 comprises an axial portion fitted into the bore of the outer ring 25 and a portion directed inwards from the edge of the adjacent axial portion of the front surfaces of the inner ring 24 and outer 25 and slightly approximating the rolling elements 26 towards its free end. The reinforcements 30 and the flexible portions 31 are annular and completely arranged in the radial space defined between the inner and outer rings 24 and in the axial space defined between the cage 27 and the plane of the radial front surface of the rings 24 and 24. 25. The coupling joints 28 and 29 therefore have no significant influence on the bulk of the coupling device 22. The flexible portion 31 can be made by overmolding a synthetic material, for example elastomer, on the metal armature 30. The flexible portion 31 partially overlaps the inward facing portion of the armature 30 and extends inwardly to engage an axial bearing surface of the inner ring 24. The flexible part 31 comprises two contact lips 32 and 33 spaced axially and in contact with the same scope of the inner ring 24 on which they rub, thus providing torque transmission economically. The coupling device has the same bulk as a bearing of equal mechanical characteristics, thanks to the insertion of the coupling joints 28 and 29 between the rings 24 and 25.

  In the embodiment illustrated in FIG. 3, the flange 17 comprises two parts 34 and 35 welded to each other, the outer portion 34 being screwed to the casing 8 and provided with a radial portion in contact with said casing. 8 and an axial portion directed away from the bead 16. The inner portion 35 comprises a large diameter axial portion welded to the axial portion of the outer portion 34, an inwardly directed radial portion free ends welded to each other axial portions of the portions 34 and 35 and an axial flange directed towards the rolling elements 12 of the rolling bearing 9 and fitted on an axial bearing surface 36 of the outer ring 11 of the rolling bearing 9.

  The coupling device 22 comprises a rolling bearing 37, similar in type to the rolling bearing 9, but having a much smaller diameter of rolling elements with an outer ring 38 fitted into the bore of the large diameter portion of the inner portion 35 of the flange 17.

  The coupling device 22 also comprises a coupling joint 40, seen in more detail in FIG. 4, fitted into the bore of the inner ring 39 of the bearing 37 and provided with a lip 44 which rubs against an outer cylindrical bearing surface of the inner ring 10 of the rolling bearing 9. The axial portion 21 of the hub 20 is fitted into the bore of the coupling joint 40 in line with the rolling bearing 37.

  The spacer 5 is in direct contact with the inner ring 10 of the rolling bearing 9, the seal 40 having a diameter greater than that of said spacer 5.

  More specifically, the ring-shaped seal 40 comprises an armature 41 in the form of an L-shaped cup having an axial portion and an inwardly extending radial portion, and an flexible part 42 covering largely the armature 41, in particular on the two outer and inner faces of the axial portion of the armature 41 to ensure excellent rotational solidarity of the seal 40 with the inner ring 39, on the one hand, and with the hub 20, on the other hand. The flexible portion 42 also extends inwards and towards the rolling elements 12 of the rolling bearing 9 and is provided with a lip in frictional contact with the inner ring 10. The coupling joint 40 is completed by a 43 annular spring, ensuring the radial clamping of the lip 44 of the flexible portion 42 on the inner ring 10 of the rolling bearing 9 and therefore the transmission of a friction torque between said inner ring 10 and the hub 20. The presence a spring 43 is particularly well suited for the transmission of calibrated friction torque, the spring maintaining a constant radial force of clamping the lip 44 on the inner ring 10, regardless of the wear of the lip 44.

  The inner portion 35 of the flange 17, on the one hand, ensures in cooperation with the outer portion 34, the axial retention of the outer ring 11 of the rolling bearing 9 and, on the other hand, supports the outer ring 38 of the bearing to bearing 37 ensuring its axial and radial retention relative to the outer ring 11 of the rolling bearing 9, thus avoiding that the flexible portion 42 of the coupling seal 40 is excessively close to the cage 13 of the rolling bearing 9, or that the friction torque does not vary due to possible eccentricity of the coupling ring 40 relative to the inner ring 10. The coupling joint 40 has an outer diameter substantially equal to the bore of the inner ring 39 and is therefore not bulky radially.

  The embodiment illustrated in FIG. 5 approaches the previous one, except that the outer ring 38 of the rolling bearing 37 is in direct contact with the outer ring 11 of the rolling bearing 9 by their respective radial front surfaces and is fixed by a weld bead 44. The flange 17 has a radial portion of large diameter screwed to the housing 8, an axial portion in the bore of which is disposed the outer ring 38 of the rolling bearing 37 and a radial flange directed towards the interior from the end of the axial portion opposite to the radial portion and which maintains the axial position of the outer rings 11 and 38 of the rolling bearings 9 and 37. A portion of the rolling bearing 37 and the portion axial flange 17 are projecting into an annular recess formed by the hub 20, which ensures excellent use of the available axial space.

  It can also be seen that the rolling bearing 37 is provided on the side of the hub 20 with a seal 45. As illustrated in the figures, the rolling bearing 37 may be without a seal on the opposite side. because of the seal offered by the coupling joint 40 and the seal 14 of the rolling bearing 9.

  In the embodiment illustrated in FIG. 6, the flange 17 and the rolling bearing 37 are similar to those illustrated in FIG. 5. The axial portion 21 of the hub 20 is directly fitted into the bore of the inner ring 39 of the rolling bearing 37, while the coupling joint 40 is fitted into the bore of the axial portion 21 of said hub 20. The coupling joint 40 has a shape slightly different from that illustrated in Figures 4 and 5, with a portion flexible member 42 having a general U-shape of which an axial branch is fitted into the hub 20 and the end of a substantially axial branch is equipped with the spring 43 and rubs on a ring 46 of thin rectangular cross-section fitted on a part of its axial length on an outer axial surface of the inner ring 10 of the rolling bearing 9 and axially surrounding a portion of the spacer 5, thereby providing an outer surface of friction at the coupling joint 40. The coupling joint 40 is particularly compact radially and axially by occupying an axial space less than or equal to the axial length of the inner ring 39 while having an outer diameter smaller than the bore of the inner ring 39. The ring 46 may consist of a portion of tube of small thickness and of suitable length, for example less than the length of the inner ring 10.

  As can be seen in FIG. 7, the speed of rotation of the fan increases less rapidly than that of the alternator from a certain speed, for example 4000 rpm, has a monotonous shape of decreasing slope in a range intermediate speeds, for example between 4000 and 14000 t / minute, then has a relatively constant low slope beyond.

  The maximum torque transmissible by the coupling device depends on the material chosen to produce the flexible part of the prestressing exerted and the area of the facing surfaces. It is thus possible to calibrate, by construction or adjustment, the maximum torque that can be transmitted between the driving element and the driven element. The maximum torque can be predefined, so that at a given rotational speed of the fan, the aerodynamic drag torque of the fan will exceed the maximum transmittable torque. There will then be a relative rotation between the fan rotor and the drive shaft. The speed of the fan may grow slowly depending on the torque-speed curve of a fan which is monotonous increasing. The coupling device is compact and can easily be placed inside an alternator. It provides both a reduction of fan noise and a reduction in power consumption by limiting the torque transmitted to the fan.

  The coupling device is in the form of a simple bearing with deep groove rings or with sheet metal rings equipped with coupling seals.

Claims (1)

11 CLAIMS   1-Coupling device (22) between a driving element for rotating a driven element, the driven element being mounted on the driving element by means of a bearing comprising two concentric rings (24, 25) between which is disposed at least one row of rolling elements (26) in contact with raceways provided on said rings, the passage of torque between the driving element and the driven element being effected by mechanical coupling, characterized in that it comprises an annular friction element ensuring the passage of a calibrated torque limited to a predefined value between the driving element and the driven element, said friction element cooperating with an annular bearing surface of the driving element and having a diameter less than or equal to the outside diameter of said bearing.   2-Device according to claim 1, characterized in that the friction element is in the form of a seal (28).   3-Device according to claim 1 or 2, characterized in that the friction element is supported by one of the rings (25) of the bearing and is in frictional contact with the other ring (24) of said bearing.   4-Device according to any one of the preceding claims, characterized in that it comprises two friction elements disposed within said bearing.   5-Device according to any one of claims 1 to 3, characterized in that the friction element is integral with the driven member and comes into frictional contact with an annular bearing surface of the driving element.   6-Device according to claim 5, characterized in that the friction element is integral with the inner ring (39) of the bearing.   7-Device according to claim 5 or 6, characterized in that the friction element is in frictional contact with a bearing of the rotating ring of another bearing (9).   8-Device according to any one of the preceding claims, characterized in that one of the rings of said bearing is mounted on a non-rotating support (17).   9-Device according to claim 8, characterized in that said non-rotating support comprises the non-rotating ring of another bearing (9).   10-Device according to any one of claims 1 to 4, characterized in that the coupling element is supported by the driven member and is in frictional contact with a ring (46) belonging to the driving element.