FR2463312A1 - DEVICE FOR FIXING AND ADJUSTING MECHANICAL ELEMENTS IN THE DIRECTION OF THE AXIS ON TREES, AXES, OR THE LIKE, IN PARTICULAR FOR FIXING THE BEARINGS - Google Patents

Abstract

DEVICE INTENDED TO FIX AND ADJUST MACHINE ELEMENTS IN THE DIRECTION OF THE AXIS ON SHAFTS, AXLES OR THE LIKE, IN PARTICULAR FOR THE FIXING OF BEARINGS. AT LEAST ONE CUNEIFORM DISC SHOWS A RECESS AND ITS THICKNESS DECREASES IN THE DIRECTION OF THE SYMMETRY AXIS, A CORRESPONDING AXIAL SUPPORT SURFACE 7 IS PROVIDED ON SHAFT 5, THIS CUNEIFORM DISC BEING ARRANGED TO SURROUND THE SHAFT 5 IN THE DIRECTION OF THE AXIS, BETWEEN THE MACHINE ELEMENT 11 TO BE FIXED AND THE SUPPORT SURFACE.

Description

The present invention relates to a device for fixing and / or

  adjust, in the direction of the axis, machine elements on shafts, axles, axles, etc. Devices of this type are used among others in the technique of fixing the bearings. A bearing inner race or a plain bearing bush are slid on a shaft or an axis, they rest on one side, for example, on the shoulder constituted by a larger diameter of the shaft, and must, on on the other side, be fixed or immobilized in the direction of the axis with respect to this larger diameter part. This is usually done using threaded nuts, shrink sleeves, circlips with washers

  Belleville or fitting rings. Also known are circlips engreg-

  In circumferential annular grooves, which have different thicknesses in the peripheral direction and which can be combined in pairs, vary in their total thickness by rotating one of the two circlips relative to the other. Such devices are known from German Patent 689,232 and German Patent Application 2,654,453. The rings are made in the form of circlips.

  and have radial holes or lugs (or ears) that allow

  try to turn them relative to each other. To allow them to be locked against accidental loosening, it is expected that the angles of variation of the thickness of these rings in the peripheral direction

  are relatively small, which ensures automatic blocking.

  It is in particular during the assembly that the known embodiments

  have considerable disadvantages: the parts, which are neces-

  still only two in number, can not produce the axial movement and, therefore, the axial fixing force, only by a rotary movement of one with respect to the other. The radial ears or holes have only a small area of attack to the peripheral force to be applied, unless they are made with dimensions relatively large compared to those of other parts; such dimensions would, however, result in an increase in the volume of the whole pair of rings. In addition, it is necessary that the rings are spaced apart, using a special tool, such as normal circlips, the same diameter as the shaft, so that they can be inserted into the annular groove provided for this purpose. It is therefore imperative that the material of the rings has a certain elasticity, which has very adverse effects when the rings are rotated relative to each other, since at least one half of each ring then has

  tendency to radially out of the annular groove. Another incon-

  Unfortunately, it is not possible to guard against accidental axial loosening, that is, for example, by the fact that the fixed part imparts to the rings a rotational movement, or as a result of vibrations or

  other external effects, than by providing additional parts.

  Moreover, the aforementioned drawbacks limit

  the field of application of the known embodiments, particularly when it is a question of producing large axial fixing forces, for example to prevent at the same time the rotational movement of the immobilized parts or in the case of the bearings which must absorb large axial forces, such as tapered roller bearings

  and angular contact ball bearings.

  Another disadvantage is the relatively large loss of the shaft, the shaft, etc., by the annular groove required for the fixing rings. For loads of any kind, such as twisting or bending, cutting a small annular groove

  resistance to that of a shaft or axis having a corresponding diameter

  to the bottom of the groove.

  The present invention aims to develop a device for fixing and / or adjust in the direction of the axis of the machine elements on shafts, axes, etc., which avoids the aforementioned drawbacks, which be constituted by

  parts that are easy to manufacture and allow for easy use.

  The present invention solves this problem

  by at least one disc - wedge-shaped which has an obvious

  the thickness decreases continuously in the direction of the axis of symmetry, a corresponding axial bearing surface being provided on the shaft, the axis, etc., and said wedge-shaped disk being arranged so as to surround the shaft, the axis, etc., in the direction of the axis, between

  the machine element to be fixed and the bearing surface.

  The particular embodiment of the disc which has the shape of a wedge in the radial direction, advantageously allows immobilization or adjustment in the direction of the axis, by a force acting in the radial direction. It is very easy to produce forces

  radials which, if necessary, are also very easily measurable.

  Advantageously, no particular surface of attack is necessary an intermediate part connecting the branches presents indeed

  The greatest thickness and therefore the maximum stability of the

  seems of the wedge-shaped disc, which gives a relative attack surface

  large, which can be machined even with simple hand tools. In addition, it is possible to easily produce very large axial forces by pressing or striking. According to another characteristic of the present invention, the shaft, the axis, etc. carries two diametrically opposite tangential grooves, the flanks of which act as axial bearing surfaces for the toric wedge disk. Compared to the circumferential annular grooves, this solution has particular advantages in terms of loads, especially in the case of axles or axles. The resistance of the axis remains intact, at least in the presence of a bending force,

  when the force is applied in the direction of the tangential grooves

  the. There is no notch effect. This application is particularly common in the art, for example in the construction of transmission mechanisms, in the automotive industry,

  and in transportation technology.

  When the axial bearing surfaces of the tangential grooves are inclined relative to the radial plane of the shaft or

  of the axis at an angle identical to the corner angle i of the cune-

  iform, all that is needed is a single component, that is, a diskununiform

  to ensure immobilization or adjustment.

  This embodiment makes it possible to solve most of the application problems. The necessary corner angle results from each particular application and is in particular a function of the displacement in the direction of the axis. It is, to a large extent, independent of the axial force required, because, as previously indicated, it can be brought to large values by the simple production of a radial force,

  even when the corner angle is large.

  According to other features of the present invention, the wedge-shaped disc is open on one side, to allow its radial insertion in the tangential grooves of the shaft, the axis, etc., which gives a workpiece having substantially the shape a U whose branches are facing and which has a thickness which decreases, for example, continuously, in the direction of the free ends of the branches. As a result, the wedge disk can. be very easily inserted, in the radial direction, in the tangential grooves of the shaft, the axis, etc., which can also, for example, be done by hand, without tools, and still results in a another important advantage when several elements must be fixed on a tree, which can happen, for example, in the construction of the transmission mechanisms,

  different elements, placed between other parts, can be im-

  mobilized or loosened, without the need to dismantle beforehand the elements in front or behind. This situation arises especially during the repairs, when it is necessary to replace the cuneiform discs. A great variety can intervene in the choice of angles of the cuneiform discs within a wide range, according to the nature of the application. However, in the case of well-defined handling modes, which have a temporary nature, it is advantageous for the disk to be in its position after the radial displacement,

  and not be pushed back to its previous position by the force of ser-

  axial rage. In such cases, the cuneiform disk according to the present invention is provided with a corner angle small enough for automatic blocking to occur on the corner surfaces. When the corner angles are larger, but also to ensure the blocking in the automatic blocking zone, the free ends of the branches of the cméform disc are, according to another characteristic of the present invention, folded towards one another, after the immobilization or positioning is completed, until they surround the shaft or the axis relying on it, these conditions making it possible to avoid with certainty any accidental radial displacement of the disk which is blocked after installation, and therefore any loosening of

device.

  According to another characteristic of the present invention,

  the cuneiform disc has a closed circle and its recess has an orifice adapted to the diameter of the shaft, which allows it to be slid

  over the shaft, in the direction of the axis, to the point of use--

  well said. This orifice continues narrowing to a diameter corresponding to the distance between the bottoms of the grooves of the shaft, the axis, etc., and the thickness of the cueiform disk increases in the direction of shrinkage. With devices of this type, having a wedge disk according to this embodiment, the radial displacement can advantageously be done under the action of pressure and / or traction forces. In this case too, we can prevent any loosening

  accidental by folding the branches towards each other.

  In cases where larger axle displacements are to be expected, other features of the present invention provide for the use of two wedge-shaped disks having the same corner angle, one of which the other so that the two front surfaces, which are then outside, are flat and parallel to each other. These two discs are arranged so as to be able to move

  radially in the opposite direction and this displacement makes it possible to obtain

  their overall thickness, and thereby the desired setting or adjustment, in this case with a double axial path. We practice

  then on the tree, the axis, etc. two tangential grooves diametrical-

  opposing surfaces whose axial bearing surfaces are parallel to the radial plane. Other elements, such as the shoulder of a larger diameter shaft section, an additional piece slid on the shaft, the housing wall, the attachment of the shaft or an annular groove with or without the usual circlips or lock washers can also be used as axial bearing surfaces. Said axial bearing surfaces provided for the wedge-shaped discs, according to a

  additional feature of the present invention,

  killed by components, such as circlips, bolts, pins, etc.,

  which are made independently of the tree or equivalent.

  The device described above is particularly suitable for

  particularly advantageous, for example, when assembling rollers or rollers

  conveyor belts. The bearings used for this purpose are often subjected to well-defined axial prestressing. The deluxe disks according to the present invention also

  to compensate axial tolerances.

  The wedge-shaped discs according to the present invention can be manufactured in a simple manner, for example by stamping prefabricated tapered tapes. The surface quality of the initial material will suffice in most cases. However, if it proved necessary, especially for small corner angles, in the area of

  automatic blocking, to give slip properties

  corner properties, these properties could be obtained by additional operations or by other post-treatments. In addition, other materials, for example plastics, can also be used for the manufacture of the discs, resulting in a modification or a simplification of machining. We can also

  give different shapes to the corner surfaces. Thus, it is ima-

  gable to provide another locking system against accidental loosening, slight dentition or stepped configuration

from the surface.

  Devices of the proposed type may be used,

  not only with the described parts, which are circu-

  res, such as shafts, axles, axles, etc., but also with parts having a polygonal or oval section. Bodies having flat and parallel surfaces, and accessible from the front side, for example plates or plates, are also suitable for

this application.

  The present invention will be better understood by means of

  the detailed description of several preferred embodiments,

  taken as non-limiting examples and illustrated by the appended drawing, in which: - Figure i is a side view of a device, when using a wedge-shaped disc on a shaft or axis; FIG. 2 is a front view of the device according to FIG. 1; FIG. 3 is a front view of a device comprising a wedge-shaped disk, the ends of the branches being folded over; - Figure 4 is a side view of a device, when using two wedge-shaped discs; and FIG. 5 is a sectional view of a device for fixing carrying rollers, the fastening being provided by two

wedge-shaped discs.

  Figures I and 2 represent, according to angles of view

  different, fixing in the direction of the axis, by a single wedge-shaped disc.

  The wedge-shaped disc has substantially the shape of a U and has two branches 2 connected by a back 3. The thickness of the branches 2 decreases towards their end 4, which can be seen in particular in Figure 1. This gives the corner angle 'c'. The axis or the shaft 5 carries tangential grooves 6 cut in its mass and diametrically opposite, whose inclination, with respect to the radial plane of the axis or of the shaft 5 is identical to the corner angle oC . The outer flanks of these tangential grooves 6 constitute the surfaces

  axial support 7 for the wedge surface 8 of the disk 1;

  The opposite end face 10 of the wedge-shaped disc 1 is flat and parallel to the radial plane of the axis or of the shaft 5. The distance between the inner surfaces of the branches 2 of the wedge-shaped disk 1 corresponds to the diametrical gap of the surfaces. bottom tangential grooves 6. The back 3

  which constitutes the intermediate part between the branches 2 of the cune-

  Iform 1 has the greatest thickness, referred to the entire wedge disk 1, and a large leading surface 9 to produce the radial force. When the cuneiformal disc moves, in the radial direction, in the direction of the branches 2, the front face 10 of the disc

  cuneiform i moves to the room it supports it, in the direc-

  axis or shaft 5.

  FIG. 3 shows a device comprising a wedge-shaped disc, in the case of which the ends 4 of the branches are folded towards the axis or the shaft 5 on which they are fitted, for

  lock and lock against accidental loosening.

  Thanks to this arrangement, the unified device is blocked in the direction

radial.

  Figure 4 shows the use of two cuneate disks.

  iformes 1. which have the same oGS corner angle. Tangential grooves

  diametrically opposed 6 are, in this case, parallel to the radial plane.

  The corner surfaces 8 of the two euniform discs 1 rest on each other so that the end faces 10 are flat and parallel to each other. When the two disks move in the opposite direction, in the radial direction of the axis or shaft 5, the overall thickness of the pair of wedge-shaped disks increases, after which the front face 10 of one of the wedge-shaped discs exert pressure on the external axial bearing surfaces 7 of the tangential grooves 6, and the end face 10 of the other discununiform 1,

  pressure on the part to be immobilized or fixed 11.

  Figure 5 shows a side of a roller or conveyor belt roller with its corresponding attachment. Angular contact ball bearings, used in this case, must be subjected to a well-defined axial prestressing. Two wedge-shaped disks 1 having the same wedge angle and are used. The circlip 12, fixed in an annular groove 13 which is cut in the axis 5, serves as an axial bearing surface. The necessary axial prestressing is converted into a radial force FR by means of the corner angle of the pair of cuneiform discs andappliedthrough the leading surfaces 9 of the two wedge-shaped discs.Once the fastening is completed, the ends 4 branches of the two cuneiform discs are folded

  as previously described and as shown in Figure 3, to prevent

expensive any accidental loosening.

Claims (8)

  A device for axially fixing and / or adjusting machine elements on shafts, axles, axles, etc., characterized by at least one wedge-shaped wedge disk (1) which has a recess, and whose thickness decreases continuously in the direction of the axis of symmetry, a corresponding axial bearing surface (7) being provided on the shaft, the axis (5), etc. ., and saiduniform disc (@ being arranged to surround the shaft, axle (5), etc., in the axial direction, between the machine member (11) to fix and the bearing surface (7).   2. Device according to claim 1, characterized   in that the shaft, the shaft (5), etc. carries two tangential grooves.   the diametrically opposed ones (6) whose axial bearing surfaces (7) are inclined, with respect to the radial plane of the shaft or the axis (5), and at an angle identical to the angle of wedge d wedge-shaped disc (1) 3. Device according to claim 2, characterized in that the wedge-shaped disc) is open on one side, to allow its radial insertion in the tangential grooves (6) of the tree, the axis (5), etc.   4. Device according to claim 3, characterized in that the disc (1) has a thickness which decreases, so   continuous, in the direction of the free ends (4) of its branches (2).   5. Device according to any one of claims 3 or   4, characterized by the fact that the reciprocating disc (.l) is blocked in the radial direction after insertion, the free ends (4)   of its branches being folded towards each other.   6. Device according to any one of the claims   I or 2, characterized in that the recess of the wedge-shaped disk (1) has an orifice adapted to the diameter of the shaft and a narrowed orifice and the thickness of the wedge-shaped disk (6) increases towards the narrowing. 7. Device according to i.n claim 1, characterized in that one uses two cuneiform discs ") having the same   corner angle, which are arranged so that they can move radially   in the opposite direction, and by the fact that two tangential grooves (6) diametrically opposed are practiced on the shaft, the axis (5), etc.,   whose axial bearing surfaces (7) are parallel to the radial plane.   8. Device according to any one of the claims   1 to 7, characterized in that the axial bearing surfaces (7) provided for the wedge-shaped discs (1) are constituted by components, such as circlips (12), bolts, pins, etc., which are   independently of the shaft or the like.