DE102004048720A1 - Ball bearing for main spindle of machine tool has inner ring with groove forming raceway and two outer rings with sloping surfaces forming raceway, sliding sleeve fitting over outer rings, which are spring-loaded against its rim - Google Patents

Abstract

The ball bearing for the main spindle of a machine tool has an inner ring (2) with a groove (3) forming the raceway and two outer rings (4, 5) with sloping surfaces (6, 7) which form the raceway. A sliding sleeve (9) fits over the outer rings and they are spring-loaded against its rim, which allows the bearing to compensate for thermal expansion of the spindle.

Description

Territory of invention

The The invention relates to a ball bearing according to the preamble Features of claim 1, which is particularly advantageous is suitable for storage of the main spindle of a machine tool but also for the storage of the rotor of an electric motor or other circulating machine parts can be used.

background the invention

the Professional in the field of rolling bearing technology It is well known that to guide and support a rotating machine part at least two at certain distances from each other arranged bearings are required. Does it support the Wave in ordinary Way in two radial bearings, the problem occurs that the distances of the Bearing seats on the shaft and in the housing match only within the limits of manufacturing tolerances. Furthermore heated The wave is usually stronger under operating conditions than the housing, so that the temperature-related Längendiffe limits the wave in must be compensated for the bearings. The longest proven possibility to compensate for these manufacturing tolerances and differences in length is therefore, to guide the shaft only in a fixed bearing in the axial direction while on the other bearing by a floating bearing the different distances either at the seat of the inner ring, at the seat of the outer ring or in the warehouse itself by moving the bearing rings to each other be compensated. While as a fixed bearing such a shaft bearing depending on the required Accuracy of the axial guidance of Shaft mainly deep groove ball bearings, spherical or tapered roller bearings or double row or two single row angular contact ball bearings proved to be particularly suitable The simplest way of moving bearings is through cylindrical roller bearings or Needle roller can be realized because of these types of bearings a shift of the rolling body wreath on the track of each bordlosen bearing ring or the shaft possible is.

Another possibility for the realization of a floating bearing in the storage of a machine tool main spindle also provides in the EP 926 368 A2 disclosed ball bearings, in which a raceway with a groove-shaped ball raceway and a second raceway is formed with a longitudinally planar ball raceway and arranged between the races bearing balls made of ceramic. Due to the design of the bearing with a defined radial clearance is to be achieved that the bearing has both a sufficient seat on the shaft and in the housing and a favorable operating clearance, while the floating bearing function is ensured by axial displacement of the bearing rings in the region of the flat tread.

When using cylindrical roller or needle bearings as a floating bearing of a machine tool main spindle, it has proved to be disadvantageous that these bearings usually have a high radial stiffness, resulting in different temperatures at different temperatures between inner and outer ring or between shaft and outer ring by different thermal expansion in an increasing Radial tension in the bearing noticeable. The ever-increasing by this temperature-induced radial stress friction between the bearing rings and the rolling elements can be so strong that the permissible operating temperature of the bearing is exceeded by the resulting frictional heat and the required lubricating film between the rollers and the bearing rings to the partial burning of the lubricant and the premature failure of the camp breaks down locally. Also, the ability to form such bearings to the extent of the highest possible radial strain smaller is not a solution to the problem, if there is a requirement for accuracy reasons, the floating bearing of the main spindle bearing without radial clearance or even with slight preload must be mountable. That in the EP 926 368 A2 Although disclosed ball bearing acts against such a temperature-induced radial stress in the bearing by its defined radial clearance, it has the disadvantage, however, that it has only a low static load and thus in so-called crash cases in which the bearing is suddenly exposed to extremely high point load, too Material damage and ultimately to total failure tends.

By the DE 197 44 280 A1 In addition, an axial-radial ball bearing is known, which is suitable for supporting oscillating movements on looms and essentially arranged from an inner bearing ring with a groove-shaped ball track and two outer bearing rings with obliquely arranged flat ball raceways and between these three ball raceways and with this is in each case in point contact bearing balls. In addition, an outer bearing sleeve is formed on the two outer bearing rings under prestressing via two resilient seals, so that a three-point bearing which is free of play both axially and radially is formed. At the same time, the seals act as compensating elements, by means of which the light preload transfers the load over all the bearing balls evenly from the inner bearing ring to the two outer bearing rings and the risk of brinelling or tribocorrosion is to be reduced.

With Such a three-point bearing, it is by the with the outer bearing rings in operative connection elastic seals in limited Dimensions though possible, also temperature-induced radial tension between the inner Bearing ring and the outer bearing rings However, such a bearing is for the storage of the main spindle a machine tool not suitable, since its axial elasticity is not sufficient, occurring in such storage, speed and temperature-related changes the internal clearance and preload in the bearing without damage compensate. Also a compensation of temperature-related differences in length the main spindle in the bearings is with such a three-point bearing not possible, since this first elaborate activities would be necessary to form the camp as a floating bearing.

Task of invention

outgoing from the stated disadvantages of the solutions of the prior art Therefore, the invention is the object of the invention, a Ball bearing, in particular for supporting the main spindle of a machine tool, to design, with which it under the demand without radial play or even be mounted with slight preload by simple and cost-effective activities possible is, both temperature-related differences in length the main spindle opposite their fixed seat as well as temperature-induced radial tension within the warehouse.

description the invention

According to the invention this Task in a ball bearing according to the preamble of the claim 1 solved this way that the ball bearing by a the outer bearing rings and enclosing across from the first outer bearing ring rigid sliding sleeve and by the against a return spring force axially displaceable arrangement of the second outer bearing ring within this sliding sleeve both as temperature-related differences in length the main spindle opposite their fixed seat compensating movable bearing as well as temperature-induced radial stresses balancing between the inner bearing ring and the outer bearing rings, in preloaded three-point bearing is formed.

According to claim 2, it is a first possibility a rigid arrangement of the first outer bearing ring of the ball bearing across from the sliding sleeve if this is preferred as fixed by the bearing balls, on a front-side radial web and on the inner circumferential surface of the sliding sleeve fitting Single component is formed. The frontal radial web at the Sliding sleeve can either by a chipping or by an after inside beading the edge of the sliding sleeve or by an edge in a circumferential groove in the inner circumferential surface of the sliding sleeve used snap ring are formed.

A particularly preferred alternative possibility, a rigid arrangement the first outer bearing ring opposite the ball bearing the sliding sleeve it's about it However, if the first outer bearing ring of the ball bearing according to claim 3 steps formed on an edge portion of the inner circumferential surface of the sliding sleeve and as with the sliding sleeve one-piece integral component is formed. The one-piece education the sliding sleeve with the first outer bearing ring Above all, it has the advantage of increasing manufacturing and assembly costs for the formed according to the invention Ball bearings can be lowered significantly and that by the lower Space requirement, the design freedom is increased.

When advantageous embodiment of the invention designed according to the ball bearing it will according to claim 4 further proposed, the outer circumferential surface of the sliding sleeve as Sliding surface for Floating seat of the ball bearing in a housing and the inner surface of the sliding sleeve as a sliding surface for the axially displaceable second outer bearing ring train.

According to claim 5, the sliding sleeve of the ball bearing for this purpose on an at least twice the increased width relative to the inner bearing ring, while the first outer bearing ring of the ball bearing is formed with a maximum of half the width of the inner bearing ring corresponding width. Although the doubled increased width of the sliding sleeve thereby unfavorably increases the installation dimension of the ball bearing, but usually before handenem installation space ensures such a sliding sleeve that the ball bearing does not tilt in temperature-induced axial displacement in the bearing seat and thus possibly loses its movable bearing function. In addition, the sliding sleeve for the realization of slippery surfaces according to claim 6, both on its outer surface and on its inner surface a friction-reducing coating, such as a Duralloy ^® coating, so as to a permanent smooth axial displacement of the ball bearing in the housing and the second outer bearing ring within the ball bearing.

In accordance with claim 7, the second outer race of the ball bearing is suitably Wei training of the inventively designed ball bearing arranged in the sliding sleeve, that it rests under the bias of the return spring force with its end face on the raceway side end face of the first outer bearing ring and on the inner circumferential surface of the sliding sleeve.

The on the second outer bearing ring acting return spring force is doing according to the claims 8 and 9 preferably by a bearing ring axially opposite to inside arranged the sliding sleeve Spring pressure ring generated with its peripheral surface on the inner surface of the sliding sleeve abuts and with its outer side surface against a in a circumferential groove in the inner circumferential surface of the sliding sleeve supported snap ring is supported. Instead of such a snap ring, it is also possible, the rear support of the spring pressure ring by a cutting Anformung or by a inward beading the edge of the sliding sleeve to realize. This sets for However, the mountability of the ball bearing preceded that the first outer bearing ring as Single component is formed, in turn, by a snap ring to the sliding sleeve is fixed.

To Claim 10, it is another feature of the spring pressure ring of the formed according to the invention Ball bearing, that this in his the second outer bearing ring facing side surface several evenly spaced apart having axial blind holes, in each of which one ends several compression coil springs are added. Instead of a number however, it is also possible to use an equal number of compression coil springs matching elastomeric elements with one end in these blind holes or the return spring force of the spring ring by a facing at its second outer bearing ring side surface adjacent leaf spring or by an elastomeric ring or the like to create.

For transmission the return spring force of the spring ring on the second outer bearing ring is the second outer bearing ring according to claim 11 in a further appropriate development of the inventively designed Ball bearing as integral component with a molded back and the same outer diameter having formed further pressure ring, the profile cross-section at least approximately corresponds to the profile cross section of the spring pressure ring. By a such one-piece design of the second outer bearing ring with this another pressure ring is doing as in the one-piece training the sliding sleeve with the first outer bearing ring achieved that the manufacturing and assembly costs for the ball bearing according to the invention reduce further. However, there is also the possibility of training in the first outer bearing ring as a single component and the second outer bearing ring and the other Form pressure ring as individual components, with the advantage that standard three-point bearings in the sliding sleeve used and in accordance with the invention can be trained.

By the requirements 12 and 13 will finally be in a further embodiment of the inventively designed ball bearing nor suggested that the one connected to the second outer bearing ring Pressure ring in its the spring pressure ring facing side surface a having the same number of axial blind holes as the spring pressure ring. These blind holes are axially opposite the blind holes in the spring-loaded ring arranged and serve to receive the other ends of the Compression coil springs of the spring pressure ring. Especially advantageous is it about it in addition, when the second outer race the ball bearing together with the pressure ring formed on the back on its outer diameter an at least the full width of the inner bearing ring of the ball bearing corresponding width, since thus also a tilting the second outer bearing ring at its conditional by radial stresses in the ball bearing axial displacement in the sliding sleeve is avoided.

The formed according to the invention Ball bearing, in particular for supporting the main spindle of a machine tool, thus faces known from the prior art bearings has the advantage that it without elaborate Adjustment procedure with slight preload or without radial play can be mounted in the corresponding bearing seat of the machine tool and by the arrangement of the outer bearing rings enclosing and across from the first outer bearing ring rigid sliding sleeve and by the axially displaceable against a return spring force Arrangement of the second outer bearing ring inside this sliding sleeve is capable of both temperature-related length differences of the main spindle across from their fixed seat as well as temperature-induced radial tension within the warehouse.

Short description the drawings

A preferred embodiment of the inventively designed Ball bearing will be described below with reference to the accompanying drawings explained in more detail. there demonstrate:

1 a cross section through the drive of a machine tool with a trained in a fixed bearing and in an inventive Ball bearing mounted main spindle;

2 an enlarged view of the detail Z according to 1 with a first embodiment of the invention designed according to the ball bearing;

3 an enlarged view of the detail Z according to 1 with a second embodiment of the inventively embodied ball bearing.

Full Description of the drawings

In 1 is schematically shown the drive of a machine tool, which essentially consists of an unspecified electric motor and a driven by this main spindle 10 consists. This main spindle 10 is clearly visible with one end in two also unspecified angular contact ball bearings stored as a fixed seat 11 within a housing 16 are formed. The other end of the main spindle 10 is in contrast in a ball bearing 1 stored, which, as described below, as a floating seat 15 the main spindle 10 inside the case 16 is trained.

From the 2 and 3 it shows that the ball bearing 1 essentially from an inner bearing ring 2 with a groove-shaped ball track 3 and from a first and a second outer bearing ring 4 . 5 with two beveled ball raceways 6 . 7 exists, being between the three ball raceways 3 . 6 . 7 a number with these each in point contact bearing balls 8th are arranged.

In addition, in the 2 and 3 shown that this ball bearing 1 according to the invention by an outer bearing rings 4 . 5 enclosing and opposite the first outer bearing ring 4 rigid sliding sleeve 9 and by the axially displaceable against a return spring force arrangement of the second outer bearing ring 5 inside this sliding sleeve 9 both as temperature-related differences in length of the main spindle 10 opposite their fixed seat 11 Balancing movable bearing as well as temperature-induced radial tension between the inner bearing ring 2 and the outer bearing rings 4 . 5 compensating, self-biased three-point bearing is formed.

A first possibility, a rigid arrangement of the first outer bearing ring 4 of the ball bearing 1 opposite the sliding sleeve 9 to achieve it is in 2 to see where the first outer bearing ring 4 of the ball bearing 1 as at a frontal Radialsteg 12 and on the inner circumferential surface 13 the sliding sleeve 9 fitting individual component is formed and by the bearing balls 8th rigid to the sliding sleeve 9 is fixed. A cheaper alternative, such a rigid arrangement of the first outer bearing ring 4 of the ball bearing 1 opposite the sliding sleeve 9 However, in 3 illustrated second possibility, wherein the first outer bearing ring 4 of the ball bearing 1 preferably stepped to an edge portion of the inner circumferential surface 13 the sliding sleeve 9 molded and as with the sliding sleeve 9 one-piece integral component is formed.

Furthermore, in the 2 and 3 indicated that in both embodiments shown, the outer circumferential surface 14 the sliding sleeve 9 as a sliding surface to the floating seat 15 of the ball bearing 1 in a housing 16 and the inner circumferential surface 13 the sliding sleeve 9 as a sliding surface for the axially displaceable second outer bearing ring 5 is trained. For this purpose, the sliding sleeve 9 of the ball bearing 1 an at least twice the increased width relative to the inner bearing ring 2 on while the first outer bearing ring 4 of the ball bearing 1 with a maximum of half the width of the inner bearing ring 2 corresponding width is formed. In addition, the sliding sleeve 9 both on its outer circumferential surface 14 as well as on its inner surface 13 with a friction-reducing coating 17 . 18 designed so that a permanent smooth axial displacement of the ball bearing in the housing and the second outer bearing ring is ensured within the ball bearing.

The second outer bearing ring 5 of the ball bearing 1 is there, as well as in the 2 and 3 can be seen, under the bias of the return spring force with its raceway-side end face 19 on the raceway-side end face 20 the first outer bearing ring 4 and on the inner circumferential surface 13 the sliding sleeve 9 arranged adjacent, wherein on the second outer bearing ring 5 acting return spring force preferred by a this bearing ring 5 axially opposite within the sliding sleeve 9 arranged spring pressure ring 21 is produced. This spring pressure ring 21 is clearly visible with its peripheral surface 22 on the inner circumferential surface 13 the sliding sleeve 9 and rests with its outer side surface 23 against a in a circumferential groove in the inner circumferential surface 13 the sliding sleeve 9 inserted snap ring 24 from. In his second outer bearing ring 5 facing side surface 25 has the spring pressure ring 21 In addition, a plurality of evenly spaced axial base holes 26 on, in each of which one ends of several compression coil springs 27 are included.

The power transmission of the spring pressure ring 21 on the second outer bearing ring 5 of the Kugella ger 1 then takes place in the in the 2 and 3 illustrated embodiments such that the second outer bearing ring 5 as an integral component with a rear side molded and the same outer diameter having another pressure ring 28 is formed, whose profile cross section at least approximately the profile cross section of the spring pressure ring 21 equivalent. This pressure ring 28 has in its the spring pressure ring 21 facing side surface 29 an equal number of axial blind holes 30 like the spring pressure ring 21 on, in each of which the other ends of the compression coil springs 27 of the spring pressure ring 21 are included. To tilt the second outer race 5 in which by radial tension in the ball bearing 1 conditional axial displacement in the sliding sleeve 9 To avoid, the second outer bearing ring has 5 in addition, together with the pressure ring formed on the back 28 at its outer diameter at least one width, the full width of the inner bearing ring 2 of the ball bearing 1 equivalent.

1

ball-bearing

2

internal bearing ring

3

Ball track of 3

4

first outer bearing ring

5

second outer bearing ring

6

Ball track of 4

7

Ball track of 5

8th

bearing balls

9

sliding sleeve

10

main spindle

11

Bearing seat

12

radial web

13

Inner lateral surface of 9

14

Outer jacket surface of 9

15

Loslagersitz

16

casing

17

Coating of 13

18

Coating of 14

19

runway-side end face of 5

20

runway-side end face of 4

21

Spring pressure ring

22

peripheral surface

23

outer side surface of 21

24

snap ring

25

Side surface of 21

26

Ground holes in 21

27

Compression coil springs

28

pressure ring

29

Side surface of 28

30

Ground holes in 29

Claims (13)

Ball bearing, in particular for supporting the main spindle of a machine tool, which consists essentially of an inner bearing ring ( 2 ) with a groove-shaped ball track ( 3 ) and a first and a second outer bearing ring ( 4 . 5 ) with two beveled ball raceways ( 6 . 7 ), wherein between the three ball raceways ( 3 . 6 . 7 ) a number of these each in point contact bearing balls ( 8th ) are arranged, characterized in that the ball bearing ( 1 ) by an outer bearing rings ( 4 . 5 ) and opposite the first outer bearing ring ( 4 ) rigid sliding sleeve ( 9 ) and by the axially displaceable against a return spring force arrangement of the second outer bearing ring ( 5 ) within this sliding sleeve ( 9 ) as well as temperature-related length differences of the main spindle ( 10 ) opposite its fixed seat ( 11 ) compensating movable bearing as well as temperature-induced radial stresses between the inner bearing ring ( 2 ) and the outer bearing rings ( 4 . 5 ) compensating, self-biased three-point bearing is formed. Ball bearing according to claim 1, characterized in that the first outer bearing ring ( 4 ) of the ball bearing ( 1 ) preferably as by the bearing balls ( 8th ) rigidly to the sliding sleeve ( 9 ) fixed, at a frontal Radialsteg ( 12 ) and on the inner surface ( 13 ) of the sliding sleeve (..) fitting single component is formed. Ball bearing according to claim 1, characterized in that the first outer bearing ring ( 4 ) of the ball bearing ( 1 ) preferably stepped on an edge portion of the inner circumferential surface ( 13 ) of the sliding sleeve ( 9 ) and as with the sliding sleeve ( 9 ) One-piece integral component is formed. Ball bearing according to claim 2 or 3, characterized in that the outer circumferential surface ( 14 ) of the sliding sleeve ( 9 ) as a sliding surface to the movable bearing seat ( 15 ) of the ball bearing ( 1 ) in a housing ( 16 ) and the inner surface ( 13 ) of the sliding sleeve ( 9 ) as a sliding surface for the axially displaceable second outer bearing ring ( 5 ) is trained. Ball bearing according to claim 4, characterized in that the sliding sleeve ( 9 ) of the ball bearing ( 1 ) at least twice the increased width relative to the inner bearing ring ( 2 ) during the first outer bearing ring ( 4 ) of the ball bearing ( 1 ) with a maximum of half the width of the inner bearing ring ( 2 ) is formed corresponding width. Ball bearing according to claim 5, characterized in that the sliding sleeve ( 9 ) both on its outer circumferential surface ( 14 ) as well as on its inner circumferential surface ( 13 ) with a friction-reducing coating ( 17 . 18 Is formed), for example with a Duralloy ^® coating. Ball bearing according to claim 6, characterized gekenn records that the second outer bearing ring ( 5 ) of the ball bearing ( 1 ) under the bias of the return spring force with its raceway-side end face ( 19 ) on the track-side end face ( 20 ) of the first outer race ( 4 ) and on the inner surface ( 13 ) of the sliding sleeve ( 9 ) is arranged adjacent. Ball bearing according to claim 7, characterized in that on the second outer bearing ring ( 5 ) acting return spring force preferably by a this bearing ring ( 5 ) axially opposite within the sliding sleeve ( 9 ) arranged spring pressure ring ( 21 ) is produced. Ball bearing according to claim 8, characterized in that the spring pressure ring ( 21 ) with its peripheral surface ( 22 ) on the inner circumferential surface ( 13 ) of the sliding sleeve ( 9 ) and with its outer side surface ( 23 ) against a in a circumferential groove in the inner circumferential surface ( 13 ) of the sliding sleeve ( 9 ) snap ring ( 24 ) is supported. Ball bearing according to claim 9, characterized in that the spring pressure ring ( 21 ) in its second outer race ( 5 ) facing side surface ( 25 ) a plurality of evenly spaced axial base holes ( 26 ), in each of which one ends of a plurality of compression coil springs ( 27 ) are included. Ball bearing according to claim 10, characterized in that the second outer bearing ring ( 5 ) as an integral component with a rear-shaped and the same outer diameter having further pressure ring ( 28 ) is formed whose profile cross section at least approximately the profile cross section of the spring pressure ring ( 21 ) corresponds. Ball bearing according to claim 11, characterized in that the pressure ring ( 28 ) in its the spring pressure ring ( 21 ) facing side surface ( 29 ) an equal number of axial blind holes ( 30 ) like the spring pressure ring ( 21 ), in which in each case the other ends of the compression coil springs ( 27 ) of the spring pressure ring ( 21 ) are included. Ball bearing according to claim 12, characterized in that the second outer bearing ring ( 5 ) of the ball bearing ( 1 ) together with the pressure ring formed on the back ( 28 ) at its outer diameter at least the full width of the inner bearing ring ( 2 ) of the ball bearing ( 1 ) has corresponding width.