ITTO20110852A1 - BEARING UNIT WITH TWO CORE BODIES VOLVENT - Google Patents

Description

Description accompanying a patent application for industrial invention entitled: TWO CROWN BEARING UNIT OF ROLLING BODIES

DESCRIPTION

The present invention relates to a double row rolling element bearing unit.

Double-row rolling element bearing units have an axis of rotation, and comprise an outer ring provided with a sliding track for each ring of rolling elements, and an inner ring composed of two half rings arranged axially side by side and each equipped with a respective sliding track for a relative ring of rolling elements.

Double-row rolling element bearing units of the type described above are advantageously used in different applications such as supporting rotating shafts, or bearing-wheel hub assemblies, in which case the bearing units are mounted on a hub to allow rotation of the hub with respect to an external upright connected to a vehicle pillar. In this type of application, the bearing units must be able to be subjected to a determined axial preload to ensure correct operation and this preload is usually ensured by means of a tightening nut.

In bearing-wheel hub assemblies, the tightening nut is screwed to one end of the hub and close to one of the two half-rings, the other half-ring being arranged against an axial stop of the hub. In mounting on rotating shafts, the preload by means of the clamping nut can be carried out as in the case described above for the hub if it is possible to mount the bearing unit near the clamping nut and a free end of the rotating shaft. Whereas, should it be necessary to mount the bearing unit in a remote position from the relative tightening nut, one or more spacers are mounted on the shaft between the bearing unit and the tightening nut to transmit the axial tightening thrust from the nut. to the inner ring.

In this second hypothesis, the assembly of the bearing unit may be complex and, above all, it may not be suitable for a precise transmission of the application of the preload on the bearing unit itself.

Furthermore, both in the case of single-wheel bearing assemblies and in the case of rotating shafts, it may be necessary to replace the initial assembly bearing units with spare bearing units, the diameter of whose inner ring may, however, not be of the size suitable to be firmly mounted either on the hub, or on the shaft. In these cases, therefore, we resort to the use of bushings of calibrated thickness to obviate the different dimension between the internal diameter in the internal ring and the external diameter of the hub or shaft, leading, even in these situations, to rather complex assemblies. and, often, not balances.

The purpose of the present invention is to produce a double row ball bearing unit, which can be used in different applications without the need to impart and calibrate an axial preload on the bearing unit itself during installation, and can also be supplied with an inner ring of standard dimensions regardless of the diameter of the body on which it will be installed.

According to the present invention, a double-row rolling element bearing unit having the characteristics set out in the appended claims is provided.

The invention will now be described with reference to the attached drawings, which illustrate a non-limiting example of embodiment, in which:

Figure 1 is a sectional view of a first preferred embodiment of a double-row rolling element bearing unit made according to the present invention; And

Figure 3 is a sectional view of a detail of a second preferred embodiment of the double-row rolling element bearing unit of Figure 1.

With reference to Figure 1, 1 denotes as a whole a double-row bearing unit 2 of rolling bodies.

Here and in the following of the description, reference will be made by way of non-limiting example to a bearing unit 1 with two rows 2 of balls, it being possible however to extend everything described also to bearing units provided with two rows 2 of rollers, or provided with a crown of rollers and a crown of spheres.

Unit 1 has a rotation axis A, and comprises an outer ring 3 coaxial to axis A and provided with a sliding track 4 for each crown 2 of balls, and an internal ring 5, which is mounted inside of the outer ring 3 and is composed of two identical half rings 51 and 52 arranged axially side by side close to each other and each equipped with a respective sliding track 6 for a relative crown 2 of balls.

In the embodiment illustrated in Figure 1, the sliding tracks 6 of the half rings 51 and 52 are arranged axially offset with respect to the relative tracks 4 of the outer ring 3, and are also arranged axially outside the tracks 4 themselves in such a way unit 1 to be configured as an oblique bearing unit with contact angles preferably, but not necessarily having an amplitude equal to 45 ° and with a capacity to withstand high axial loads in both directions.

The unit 1 also comprises a bushing 20, which is preferably made of metallic material, and is mounted through both half-rings 51 and 52 to close together the half-rings 51 and 52 themselves, equally forcing them axially against each other. the other and imparting to the entire unit 1 a preload of a determined value.

The bush 20 comprises a central cylinder body 21 delimited on the outside by a cylindrical surface 22 having an external diameter FI having dimensions equal to the dimensions of an internal diameter F2 of the internal ring 5, and delimited on the inside by a coaxial cylindrical surface 23 to the surface 22 and to the axis A and having a respective internal diameter F3 of smaller dimensions than the dimensions of the diameter F1.

The bush 20 is provided with two ends 24 and 25 axially opposite and axially delimiting the cylindrical body 21, of which, in the example described here, the end 24 is defined by a shoulder 26 formed, or by a flange transversal to the axis A and integral with the body 21, made before the bush 20 is inserted inside the two half-rings 51 and 52, while the end 25 is defined by a shoulder 27 to be formed, or by a shoulder whose realization takes place only after the cylindrical body 21 has been inserted inside the internal ring 5 and until the shoulder 26 reaches axial abutment against the relative half ring 51.

According to an example of embodiment of the bearing unit 1 illustrated with a dotted line in Figure 1, both axially opposite ends 24 and 25 can be defined by respective shoulders 26 'and 27 to be formed, or by shoulders whose realization takes place only after the cylindrical body 21 has been inserted inside the inner ring 5. In this case, the formation of the shoulders 26 'and 27 can take place simultaneously, or the two shoulders 26' and 27 can be formed in succession to each other.

The shoulder 27 is obtained by deformation of the end 25 starting from an annular portion, indicated with 29 and dashed in Figure 1, which is turned cold, preferably by rolling, close to the relative half-ring 52, imparting to the bearing unit 1 a preload of a certain value.

Likewise, if the other shoulder 26 'were also a shoulder to be formed, this too would be obtained by deformation of the relative end 24 starting from an annular portion, indicated with 29' and dashed in Figure 1, which is cold-folded, preferably by rolling, close to the relative half-ring 51, imparting to the bearing unit 1 a preload of a determined value if the other shoulder 27 is already formed or is simultaneously forming.

The cylindrical body 21 also has an annular groove 30, which is formed in the surface 22 substantially starting from an internal corner 31 of the half-ring 52, and defines, in the cylindrical body 21, a bending portion 32 having a reduced radial thickness with respect to an average radial thickness of the cylindrical body 21 itself in order to facilitate the folding, preferably by rolling, of the shoulder 27 to be formed.

In the case of two shoulders to be formed, the cylindrical body 21 has, for each shoulder, an annular groove 30, which is formed in the surface 22 substantially starting from an internal corner 31 of the relative half-ring 51 and 52, and defines, in the body 21 cylindrical, a respective folding portion 32 having a reduced radial thickness with respect to an average radial thickness of the cylindrical body 21 itself in order to facilitate the folding, preferably by rolling, of the relative shoulder 26 'and 27 to be formed.

The bearing unit 1 described above, in addition to being simple to manufacture, has innumerable advantages which make it not only particularly versatile, but also easy and economical to implement on multiple applications. In fact, with the bearing unit 1 of the present invention, it is possible to always use the same type of standard inner ring 5 for any application, being able to obviate any differences in diameter by choosing the thickness of the bushing 20, or by making a cylindrical body 21 with a difference between the values of the diameters FI and F3 equal to the difference between the diameter F2 of the inner ring 5 and an outer diameter of the body on which the bearing unit 1 is to be installed.

Furthermore, since with the cold deformation process, preferably by rolling, of the shoulder 27, or of the shoulders 26 'and 27, it is possible to impart a determined preload to the bearing unit 1 when assembling the bearing unit 1 itself, the subsequent installation of the latter will be particularly rapid even regardless of its actual location, or regardless of its proximity to axial locking elements or not. Furthermore, elements whose assembly will not require any further calibration since they have the sole and sole purpose of axially fixing the position of the bearing unit 1.

In other words, the bearing unit 1 described above brings practical and economic advantages not only to the manufacturer, who will be able to use internal rings 5, or half rings 51 and 52, of standard dimensions by playing on the thickness of the cylindrical body 21 to adapt the unit bearing 1 to the different external diameters of the various applications, and, moreover, using for the production of the bushing 20 also a metal material less valuable than the metal material of the rings 3 and 5, but it also brings practical and economic advantages to the user, who it will receive a bearing unit 1 ready to be installed without any further necessary adjustment and without having to adopt particular and, as a rule, costly measures during installation.

In order to further increase the flexibility of use of the bearing unit 1 described above, this, as illustrated in Figure 2 and in a preferred alternative embodiment thereof to the previously described embodiment, but configurable as the previous embodiment , or with a shoulder 26 formed and a shoulder 27 to be formed, or with two shoulders 26 'and 27 to be formed, it comprises an axial thickness 70, which is defined by an annular washer 70, and is interposed between the half-ring 51 and the shoulder 26 to increase an axial length of the bearing unit 1 with respect to an axial length of the inner ring 5. In this case, before inserting the body 21 inside the inner ring 5, the washer 70 is mounted on the body 21 until it is brought in axial abutment against the shoulder 26. The overall length of the body 21 will be selected according to and of the axial width of the inner ring 5, and of the axial thickness of the washer 70 in such a way as to allow a portion 29 of sufficient axial length to protrude beyond the half ring 52 to be able to be turned over when cold.

If it is desired to further increase the overall axial length of the bearing unit 1 without having to modify the axial length of the inner ring 5, it is possible to use a second washer 70 also on the side of the shoulder 27 to be formed. The use of one or two washers 70 can also be provided if both shoulders 26 'and 27 are shoulders to be formed.

It is understood that the invention is not limited to the embodiment described and illustrated here, which is to be considered as an example of embodiment of the double-row rolling element bearing unit, which is instead susceptible of further modifications relating to forms and arrangements of parts, construction and assembly details.

Claims (10)

CLAIMS 1. Double row bearing unit (1) (2) of rolling elements, the bearing unit (1) having a rotation axis (A), and comprising an outer ring (3) provided with a sliding race (4) for each ring (2) of rolling elements, and an inner ring (5) composed of two half rings (51, 52) arranged axially side by side and each equipped with a respective sliding track (6) for a relative ring (2) of rolling elements; the bearing unit (1) being characterized in that it further comprises a bushing (20) mounted through both half-rings (51, 52) and provided with two respective end shoulders (26) (27), which are arranged close to the two half-rings (51, 52) to close the two half-rings (51, 52) themselves, and of which at least a first end shoulder (27) of the two end shoulders (26) (27) is a shoulder (27) to be formed close to the relative half ring (52). Bearing unit according to claim 1, characterized in that the bush (20) is made of preferably metallic material and comprises a central cylinder body (21) having an external diameter (FI) of dimensions substantially equal to the dimensions of a diameter ( F2) inside of the inner ring (5). 3. Bearing unit according to claim 2, characterized in that said cylindrical body (21) is provided with at least one bending portion (32) having a reduced radial thickness with respect to an average radial thickness of the cylindrical body (21) itself. Bearing unit according to claim 3, characterized in that the at least one bending portion (32) extends axially along the cylindrical body (21) starting from a respective inner edge (31) of said inner ring (5). Bearing unit according to any one of the preceding claims, characterized in that a second end shoulder (26) of the two end shoulders (26) (27) is a formed shoulder (26) and is arranged close to the relative half ring ( 51) to axially lock the half ring (51) itself on one side. 6. Bearing unit according to claim 5, characterized in that said second shoulder (26) formed is defined by a flange (26) integral with the central cylindrical body (21) and transversal to the rotation axis (A). 7. Bearing unit according to claim 5 or 6, characterized in that the first shoulder (27) to be formed is cold-turned, preferably by rolling, substantially in correspondence with a respective bending portion (32) and close to the relative half-ring (52) to pack the two half rings (51, 52) with the shoulder (26) formed by imparting to the bearing unit (1) a preload of a determined value. Bearing unit according to any one of claims 1 to 4, characterized in that a second end shoulder (26 ') of the two end shoulders (26) (27) is a shoulder (26') to be formed close to the relative half-ring (51) to close the two half-rings (51, 52) with the first shoulder (26) giving the bearing unit (1) a preload of a determined value Bearing unit according to claim 8, characterized in that the second shoulder (26 ') to be formed is folded in cold, preferably by rolling, substantially in correspondence with a respective bending portion (32) and close to the relative half-ring ( 51). Bearing unit according to any one of the preceding claims, characterized in that it comprises an axial thickness, or an axial thickness for each half-ring, interposed between the half-ring and the end shoulder (26) (27) to increase an axial length of the unit (1) bearing with respect to an axial length of the inner ring (5),