DE102012202365A1 - Mounting arrangement for pressing rolling bearing inner ring on conical bearing seat surface of shaft, has push plate engaged with inner ring, and bonnet wing nut whose ball screw thread shoots share same axis of rotation with wing nut - Google Patents

Abstract

The mounting arrangement has a bonnet wing nut (4) that is screwed on a cut screw thread (2) of a shaft (1). A push plate (10) is engaged with an inner ring (13) of a rolling bearing. The bonnet wing nut is provided with ball screw thread shoots (5,14) that share same axis of rotation with the bonnet wing nut. The path directions of both the ball screw thread shoots are different. A thrust bearing (12) is arranged between two portions (11.1,11.2) of the push plate.

Description

The invention relates to a mounting arrangement for pressing in particular an inner ring of a rolling bearing on a conical or conical bearing seat surface of a shaft.

For pressing an inner ring of a rolling bearing onto a conical or conical shaft, essentially two methods have emerged in the prior art.

According to WO 2010/15417 or EP 1775490 For this purpose, so-called hydraulic nuts are screwed onto the shaft. If the hydraulic nut has found its predetermined position on the shaft, a chamber arranged in the hydraulic nut is supplied with oil. As a result, a projecting into the chamber pressure surface out of the chamber and against the equally seated on the shaft inner ring of the bearing is pressed, whereby at the same time the inner ring is moved to its desired position on the shaft. A disadvantage of this method is considered that a hand or motor pump must be kept ready to build up the oil pressure in the chamber and that in this method a misalignment of the aufzupressenden inner ring can not be excluded. The latter is due, inter alia, to the fact that the hydraulic piston or pistons (pressure surfaces) do not have a sufficiently long guide in the hydraulic nut and no space is available for a sufficiently long guide.

The other method pressing on the inner ring of a rolling bearing is very similar to the method just described. By contrast, in the other method, no hydraulic nut, but only an assembly nut is screwed onto the shaft. By tightening this mounting nut then comes one of the annular surfaces of this mounting nut with the inner ring in contact and presses this further tightening the inner ring in its desired position on the shaft. Such a method, which is based solely on the mounting of an assembly nut and which also forms the subject of the present invention is, inter alia, in US 4,610,066 described. In this method is considered disadvantageous that it can be used only in relatively small camps. This is due to the fact that with increasing bearing size, among other things, the friction in the thread increases sharply. This has the consequence that corresponding torques for tightening the mounting nuts must be provided. Act such torques or forces on the mounting nut, damage to the thread of the mounting nut and / or the thread on the shaft can not be excluded.

Object of the invention

The invention is therefore based on the object of specifying a mounting arrangement which overcomes the disadvantages of the prior art and makes it possible to produce press connections between the shaft and inner ring of a thread, without having to provide hydraulic means for the advance.

Summary of the invention

This object is achieved by the features specified in claim 1. Advantageous embodiments and further developments of the invention are the claims 2 to 5 can be removed.

The basis of the invention is to minimize the friction occurring in methods based solely on the tightening of the mounting nut. Given in claim 1, to provide the mounting nut with at least one ball screw. The coaxial arrangement of the ball screw or the mounting nut and ensures that only the cut threads of mounting nut and shaft fix the mounting nut on the shaft. In other words, according to the invention, no driving work for moving the inner ring of the bearing starts from the mounting nut. This work is done solely by the one or more ball screws, which compared to cut threads have a significantly reduced friction. Compared to cut threads, the use of ball screws to realize the propulsion has the advantage that ball screws have a higher position accuracy. As a result, inner rings can be mounted very precisely on the shaft. Since i.ü. the ballscrews, similar to pure mounting nuts, provide annular surfaces, takes place during the compression of the inner ring with the shaft a very evenly distributed force into the inner ring of the bearing.

If two ball screws are present according to claim 2, both ball screws have an uneven gear direction and a different pitch, a so-called differential thread is created. As a result, a "translation" between the two ball screws is realized, which can be used very effectively to perform a propulsion of the inner ring on the shaft with relatively little torque. In thus translated ball screws it is possible to press with a shaft even without the use of hydraulic means inner rings with a larger diameter.

A particularly material-saving design is given if, according to claim 3, an inner ring of the ball screws and the Assembly nut form an integral unit. In this case, the cut thread is formed directly on the inner contour of the inner ring.

If two or more ball screws are used, a further material saving is given if according to claim 4, the outer ring of a ball screw simultaneously forms the inner ring of another ball screw.

A further reduction in friction is realized when, according to claim 5, the pressure plate, ie the part with which the propulsion generated via the mounting nut and the ball screw or the ball screw is introduced into the inner ring of the bearing comprises a first and a second part and between the two parts a thrust bearing is arranged. This interposition of an axial bearing ensures that the outer ring or the pressure plate of the respective ball screw, which is in physical contact with the inner ring of the rolling bearing, does not slide along the inner ring of the rolling bearing in the sense of a sliding bearing on this during its propulsion, but thanks to the rolling of the Rolling of the thrust bearing resting in their careers.

It is particularly advantageous if, according to claim 6, a measuring arrangement is connected to one of the ball screw drives, which determines the relative rotation of the respective ball screw relative to a fixed point. If, in fact, the relative rotation is known, the displacement path of the object to be pressed onto a shaft can be very accurately determined and displayed together with the known pitch of the respective ball screw drive.

Short description of the drawing

Show it:

1 a first embodiment of the invention; and

2 another embodiment of the invention

Detailed description of the drawing

The invention will now be explained in more detail with reference to FIGS.

In 1 is a wave 1 shown, which with a cut thread 2 and a conical bearing seat surface 3 is provided. For the sake of completeness, it should be noted that in 1 the conicity of the bearing seat surface 3 only for clarification of the circumstances was shown angled at an angle.

On the thread 2 is an assembly mother 4 screwed. This mounting nut 4 is from a first ball screw 5 surrounded by the mounting nut 4 and the first ball screw share a common axis of rotation. This first ball screw 5 is from one with the mounting nut 4 connected inner ring 6 , an outer ring coaxially surrounding the inner ring 7 and ball 8th formed in the axial distance between the two rings 6 . 7 are arranged. In the rings 6 . 7 are careers 9 introduced, which have a circular segment-shaped cross section and in which the balls 8th can roll off. One of these careers 9.1 is formed by a plurality of rings not connected to each other, the axial distance at the inner ring 6 are trained while the career 9.2 a continuous, the outer ring 7 spiral-shaped running track 9.2 is. All these tracks 9.1 ., 9.2 have a spherical segment-shaped, in the respective bearing rings 6 . 7 lowered profile. Will now be the outer ring 7 of the ball screw 5 set in rotation, the balls roll 8th on their careers 9 from and the outer ring 7 moves depending on the direction of rotation of the outer ring 7 either in the direction of arrow P1 or P2.

As shown in the illustration 1 can be clearly seen, is on the outer ring 7 a printing plate 10 trained, resulting in a first part 11.1 and a second part 11.2 divided. Both parts 11 stand over a thrust bearing 12 in connection.

Will now be the outer ring 7 or its first part turned so that by this rotation s of the outer ring 7 is moved in the direction of arrow P1, comes as in 1 shown - the first part 11.1 , the printing plate 10 with an inner ring 13 a aufzupressenden bearing (not shown) in physical contact. If the rotation in the direction of arrow P1 continues, there is a static friction between the first part 11.1 and in the direction of rotation of the rotating outer ring 7 fixed inner ring 13 , However, this stiction does not interrupt the propulsion of the outer ring 7 in the direction of arrow P1, because with the part standing 11.1 the outer ring 7 then thanks to the thrust bearing 12 still can be turned on.

Is the part 11.1 the printing plate 10 with the inner ring 13 in physical contact, with further rotation of the outer ring 7 the inner ring 13 then in its predetermined position on the bearing seat surface 3 pressed.

Further is 1 removable, that the inner ring 6 of the ball screw 5 with a measuring arrangement 20 is provided. Will now be the outer ring 7 of the ball screw 5 for pressing out the inner ring 13 turned on the shaft, the outer ring moves 7 at the measuring arrangement 20 past. This relative movement or rotation between the serving as a fixed point inner ring 6 and the outer ring 8th is from the measuring arrangement 20 taken and together with the known slope of the ball screw thread 5 processed in a processor (not shown) and as a displacement path of the inner ring 13 output. How ultimately the measuring arrangement 20 is formed, is indifferent, if it is suitable, the rotation or the Verdrehweg between the inner ring 6 and the outer ring 7 capture.

In the embodiment according to 2 is not just a first ball screw 5 , but also a second ball screw 14 for propulsion of the inner ring 13 on the wave 1 intended.

Notwithstanding the arrangement according to 1 are the assembly mother 4 and the inner ring 6 of the first ball screw 5 integrally formed by the inner ring 6 with a cut thread 15 is provided. This inner ring 6 is on the wave 1 screwed. As already related to 1 described, be on the first ball screw 5 the raceways 9.1 on the inner ring 6 formed by a plurality of axially spaced, mutually unconnected rings, while the raceway 9.2 , on the outer ring 7 of the first ball screw 5 this continuous, with a first slope helically edged.

Also the second ball screw 14 includes an inner ring 15 , a this inner ring 15 coaxially surrounding outer ring 16 and bullets 18 in the radial distance between the two rings 16 . 17 are arranged and on careers 19 roll off when the two rings 16 . 17 perform a relative movement to each other. As shown in the illustration 2 can be taken, are the outer ring 7 of the first ball screw 5 and the inner ring 16 of the second ball screw 14 Designed to save material as a one-piece unit. The same applies to the printing plate 10 according to 1 integral part of the outer ring 17 of the second ball screw 14 is.

The raceways 19 of the second ball screw 14 are designed to be the career path 19.1 in the outer ring 17 is formed by a plurality of unconnected and axially spaced rings and the raceway 19.2 on the inner ring 16 this also throughout, but with a second slope surrounded by a helical. Because of the two helical raceways 9.2 . 19.2 have a common gear direction and a different slopes, a reduction is provided. Will be similar to the execution according to 1 the unit of outer ring 7 of the first ball screw 5 and inner ring 16 of the second ball screw 14 set in rotation, this unit moves, for example, because of the large rises in one revolution by a dimension A in the direction of arrow P1, while through this one rotation of the outer ring 17 because of the second ball screw 14 predominant lower slope of the track 19.2 by the amount ½ A in the other direction P2 is moved back.

Is now like in 2 shown the pressure plate 10 or the outer ring 17 of the second ball screw 14 on the inner rings 13 a rolling bearing (not shown) and is the rotation of the unit of outer ring 7 of the first ball screw 5 and inner ring 16 of the second ball screw 14 continued, the pressure plate shifts 10 or the outer ring 17 in the direction of arrow P1, causing the inner ring 13 in its desired position on the shaft 1 is moved.

By that, the career 19.2 consists of a plurality of rings, the outer ring 17 not by a rotation of the unit of outer ring 7 of the first ball screw 5 and inner ring 16 of the second ball screw 14 set in rotation. As a result, in the embodiment according to 2 also in 1 necessary thrust bearings 12 omitted.

For the sake of completeness, it should be noted that the application of the invention is not to the pressing on of inner rings 13 on waves 1 is limited. Rather, the invention can be used wherever it is necessary to produce press dressings with kegligem interference fit.

LIST OF REFERENCE NUMBERS

1

 wave

2

 cut thread

3

 Bearing seat surface

4

 mounting nut

5

 first ball screw

6

 inner ring

7

 outer ring

8th

 roll

9

 raceways

10

 printing plate

11

 first, second part

12

 thrust

13

 inner ring

14

 second ball screw

15

 cut thread

16

 inner ring

17

 outer ring

18

 roll

19

 raceways

20

 measurement arrangement

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• WO 2010/15417 [0003]
• EP 1775490 [0003]
• US 4610066 [0004]

Claims (6)

Mounting arrangement with an assembly nut ( 4 ), with a cut thread, with which the mounting nut ( 4 ) on a cut thread ( 2 ) of a wave ( 1 ) is screwed, and with a pressure plate ( 10 ), which with an inner ring ( 1 ) of a rolling bearing is in relation to this on a conical or conical bearing seat surface ( 3 ) the wave ( 1 ), characterized in that the mounting nut ( 4 ) with at least one ball screw ( 5 ) and that the mounting nut ( 4 ) and all ball screws ( 5 . 14 ) share the same axis of rotation. Mounting arrangement according to claim 1, characterized in that a first and a second ball screw ( 5 . 14 ) is present and that both ball screws ( 5 . 14 ) have an uneven gear direction and a pitch different from each other. Mounting arrangement according to claim 1 or claim 2, characterized in that each ball screw ( 5 . 14 ) an inner ring ( 5 . 16 ) has that the mounting nut ( 4 ) and an inner ring ( 6 . 16 ) of a ball screw ( 5 . 14 ) form an integral unit. Mounting arrangement according to one of claims 1 to 3, characterized in that each ball screw ( 5 . 14 ) an outer ring ( 7 . 17 ), and that at least two ball screws ( 5 . 14 ) the outer ring ( 7 ) of a ball screw ( 5 ) simultaneously the inner ring ( 16 ) of another ball screw ( 14 ). Mounting arrangement according to one of claims 1 to 4, characterized in that the pressure plate ( 10 ) a first and second part ( 11.1 . 11.2 ) and between both parts ( 11 ) an axial bearing ( 10 ) is arranged. Mounting arrangement according to one of claims 1 to 5, characterized in that a measuring arrangement ( 20 ) with one of the ball screws ( 5 . 14 ), which the relative rotation of the respective ball screw ( 5 . 14 ) compared to a fixed point.

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