DE3811970A1 - Rolling bearing arrangement - Google Patents

Abstract

A rolling bearing arrangement contains the neck (2) of a work roll, the neck being supported in at least one taper roller bearing with an inner race (11) and a cylindrical roller bearing arranged on one or both sides of the taper roller bearing and having in each case an inner race (7). The inner races (7, 11) are arranged rotatably, with little radial play or a loose fit on the neck (2). To avoid the risk of smearing during the mutual contact of the end faces (17, 18) of the inner races (7, 11), at least one of the two end faces of the inner race of the taper roller bearing or the opposing end face (17) of the inner race (7) of the cylindrical roller bearing is connected to a single axial projection which engages with axial play in a guide recess in the end face (18) of the inner race (11) of the cylindrical roller bearing or the taper roller bearing and is arranged so as to be displaceable radially in sliding fashion between two circumferentially opposite side faces of the guide recess. <IMAGE>

Description

The present invention relates to a rolling bearing arrangement according to the preamble of claim 1.

In a known rolling bearing arrangement of the type specified are on both sides of a double row tapered roller bearing in each case a cylindrical roller bearing bearing the radial forces in the bore of a rolling mill frame installed (DE-OS 36 07 729). With short-term axial relief of the tapered roller bearing what often occurs in so-called traversing rollers in operation the inner ring of the Tapered roller bearing opposite the two inner rings of the two loaded cylindrical roller bearings slightly in its rotary motion slow it down. If the axial load in operation again is applied, comes the one end face of the inner ring one of the two cylindrical roller bearings against the one opposite end face of the inner ring of the Tapered roller bearing in contact and is supported on this. There is a sudden spin of the slowed inner ring of the tapered roller bearing due to friction with the faster inner ring of the cylindrical roller bearing. It there is a risk that the end faces of each other supporting inner rings when sliding in Obtain harmful lubrication around the circumference.

The invention characterized in claim 1 is in contrast the task is based on a rolling bearing arrangement of the specified Way of creating the danger of developing  Lubrication in mutual contact of the end faces of the Inner rings of the rolling bearing is turned away.

This object is achieved according to the characterizing part of claim 1.

With the rolling bearing arrangement according to the invention it is achieved that the inner ring of each angular contact bearing on one or both Sides with an inner ring of a radial load Cylindrical roller bearing is rotatably connected. Despite this non-rotatable connection, the inner ring can each Angular contact bearing opposite the or Cylindrical roller bearing inner ring somewhat in the radial direction shift, namely within the radial running play and the elastic deformation in the rolling contacts of the Cylindrical roller bearings of the rolling bearing arrangement. That way ensured that each angular contact bearing only the Axial loads and each cylindrical roller bearing only that Take up radial loads on the work roll. The inner rings of the Cylindrical roller bearings are like in journal bearings in Rolling mills common, with loose fit on the tenon put on so that they have little radial play and accordingly can wander somewhat on the pin in the circumferential direction.

Advantageous developments of the invention are in the Subclaims marked.

With the training according to claim 2 it is achieved that the Projection of the relevant end face of an inner ring in the depression of the face of the other adjacent Inner ring is guided in the radial direction. It can advantageously a very low sliding play of the projection provided between the side surfaces of the guide recess will.

The development according to claim 3 has one possibility towards making the recess groove-shaped in the radial direction, so that this with a milling cutter or the like. in the relevant  End face of the inner ring incorporated particularly easily can be.

With the training according to claim 4, the advantage is given that small mutual misalignments or misalignments of the with the projection provided inner ring relative to the associated guide recess provided inner ring to none harmful edge loading of the projection on the Lateral surfaces of the guide recess leads.

The development according to claim 5 causes that to attach of the projection on the associated end face no further Fasteners must be provided.

The development according to claim 6 has the consequence that the front jump can be made from a material that compared to the material of the associated inner ring particularly high strength and toughness with good Has sliding properties.

More advantageous, but not a matter of course Further developments of the invention are in the subclaims 7 to 10 marked.

The rolling bearing arrangement according to the invention is shown in the following Description of two embodiments in the drawings are described, described in more detail.

Show it:

Fig. 1 shows a partial longitudinal section through a rolling bearing assembly,

Fig. 2A shows an enlarged representation of the detail indicated by Z in Fig. 1,

Fig. 2B is a view in the direction of arrow V in Fig. 2A, Fig. 2C is a sectional view taken along the line XX in Fig. 2A,

Fig. 3A is an enlarged partial view of a longitudinal section through a modified bearing assembly,

Fig. 3B is an illustration in the direction of arrow W in Fig. 3A and

Fig. 3C is a sectional view taken along the line YY in Fig. 3A.

1 in Fig. 1 is an axially adjustable work roll of a rolling mill and 2 denotes a cylindrical pin arranged on the fixed bearing and operating side of this work roll 1 . On the opposite floating bearing and drive side, the work roll 1 is mounted in a four-row tapered roller bearing (not shown). The pin 2 is mounted on a double-row angular roller bearing 3 for receiving axial loads in both directions and on two single-row cylindrical roller bearings 4 , 5 for receiving radial loads in the cylindrical bore of a rolling mill frame 6 . A cylindrical roller bearing 4 or 5 is arranged on both sides of the angular contact roller bearing 3 .

Each cylindrical roller bearing 4 , 5 has an inner ring 7 , 8 arranged on the journal 2 , an outer ring 9 , 10 fixed in the bore of the rolling mill frame 6 , and a series of cylindrical rolling bodies rolling therebetween.

The angular contact roller bearing 3 consists of an inner ring 11 , two outer rings 12 , 13 and two rows of tapered rolling elements, the lines of action 14 , 15 of which are mutually arranged radially inwards.

The diameter of the cylindrical bore of the inner ring 11 of the angular contact roller bearing 3 is somewhat larger than the diameter of the bore of the two inner rings 7 and 8 of the cylindrical roller bearing 4 and 5 . In this way it is ensured that the angular contact bearing 3 only receives axial loads on the pin 2 . Otherwise, the inner rings 7 , 8 and the inner ring 11 of the on the pin 2 have a small radial play and are installed together between two shoulder rings 14 , 15 of the pin 2 with little axial play. All inner rings 7 , 8 and 11 can thus rotate or move somewhat on the pin 2 .

The inner ring 7 , 8 of the two cylindrical roller bearings 4 , 5 has at each of its two ends a radially extending, flat end face 16 , 17 . Likewise, the inner ring 11 of the angular contact roller bearing 3 has a radially extending flat end face 18 at each of its two ends.

Each end face 18 of the inner ring 11 of the angular contact roller bearing 3 is supported in the axial direction on the end face 17 of the relevant inner ring 7 or 8 opposite this.

The end face 17 of the inner ring 7 of the cylindrical roller bearing 4 shown on the left in FIG. 1 is firmly connected with a single axial projection. In the present case, this projection is formed by a fitting 19 with a substantially rectangular cross section ( FIGS. 2A, 2B and 2C). The fitting 19 is inserted in a holding recess 20 in the end face 17 of the inner ring 7 . The holding recess 20 has two opposing flat boundary surfaces 21 in the circumferential direction, which are each closely adapted to a flat side surface 22 of the adapter 19 . In this way, the fitting 19 is held in a positive manner in the circumferential direction in the holding recess 20 . A head screw 23 is screwed with its shaft into a threaded hole 24 in the end face 17 so that the fitting 19 cannot fall out of the holding recess 20 . The head of the cap screw 20 is secured by welding 25 against unscrewing from the threaded hole 24 ( FIG. 2A).

The adapter 19 engages in a guide groove 26 of the end face 18 with axial play and the guide groove 26 slidably disposed with its boundary surfaces 21 facing each other in the circumferential direction of side surfaces 27 in the radial direction. The two side surfaces 27 are flat and run parallel to one another. They also each lie in an axially directed longitudinal plane ( FIGS. 2B and 2C).

In the present case, the inner ring 11 of the angular roller bearing 3 and the inner rings 7 , 8 of the cylindrical roller bearings 4 , 5 have flat troughs filled with compact graphite and molybdenum disulphide on their two end faces 16 , 17 and 18 , respectively, on the circumference of the relevant inner ring 7 , 8 or 11 are evenly distributed. These troughs can be created by sandblasting.

FIGS. 3A, 3B and 3C show a projection which can be used in the rolling bearing arrangement shown in FIG. 1. The projection is formed as a fitting piece 28 with two circumferential boundary surfaces 21 which are connected to one another by a radially outwardly pointing convex cylindrical boundary surface 29 .

The adapter 28 can be fastened on the end face 17 of one of the two inner rings 7 and 8 of the roller bearing arrangement shown in FIG. 1 or on the end face 17 of the two inner rings 7 , 8 . In the latter case, both end faces 17 of the inner ring 11 are connected in a rotationally fixed manner to the inner ring 7 and 8, respectively, by means of a single fitting piece 28 , so that the three inner rings 7 , 8 and 11 cannot perform any rotational movements relative to one another.

The convex boundary surface 29 of the fitting piece 28 is supported radially outwards on a conformally shaped, cylindrical outer wall 30 of the holding recess 20 . Incidentally, the fitting piece 28 has a concave boundary surface 31 that points radially inwards and is supported on the lateral surface of the pin 2 .

The fitting 28 engages in a guide recess 26 of the end face 18 of the inner ring 11 with axial play. Between two side surfaces 27 of this guide recess 26 , which face each other in the circumferential direction, the fitting piece 28 is arranged so as to be slidable in the radial direction. The fitting 28 has two boundary surfaces 32 which are slightly convex in the radial direction and which can slide somewhat in the radial direction on the relevant side surface 27 of the guide recess 26 . The adapter 28 has a small amount of sliding play between the two side surfaces 27 .

Within the scope of the inventive concept, the above Modify specified embodiments constructively.

Therefore, instead of being connected to the end face 17 of the inner ring 7 or 8 , the axial projection can also be firmly connected to at least one of the two end faces 18 of the inner ring 11 of the angular contact roller bearing 3 . In this case, the guide recess is then machined into the end face 17 of the inner ring 7 or 8 concerned.

In addition, the axial projection need not be designed as a fitting piece which is firmly connected to the end face of the inner ring in question. The projection can namely be designed as a loose fitting and then - without fastening screws - connect the two inner rings to one another in the circumferential direction only by positive locking on their opposite end faces.

The projection can be used instead of a convexly curved boundary surface beveled, radially outwardly opening boundary surfaces have, each on an opposite side surface  the guide recess of the inner ring in question in radial Sliding towards something.

The projection can, by the way, with the face of the Cylindrical roller bearing or angular roller bearing in one piece be connected.

In the rolling bearing arrangement according to the invention, it is also only possible to a single cylindrical roller bearing on one of the two sides of the Inclined roller bearing, where then the inner ring of the Cylindrical roller bearing and the inner ring of the angular contact roller bearing are non-rotatably connected to each other by the single projection.

Instead of a double row tapered roller bearing, a other thrust bearing, z. B. a single or double row ball bearing, with a corresponding Inner ring may be provided.

Claims (10)

1. Rolling bearing arrangement, in particular for work rolls in rolling mills, in which a journal of the work roll with little radial play in the inner rings of at least one angular contact bearing and cylindrical roller bearings arranged on one or both sides of the angular contact bearing is mounted, the inner ring of the angular contact bearing being one on an opposing one End face of the inner ring of the cylindrical roller bearing in question has a supporting end face, characterized in that at least one of the two end faces ( 18 ) of the inner ring ( 11 ) of the angular contact roller bearing ( 3 ) or the end face ( 17 ) of the inner ring ( 7 , 8 ) opposite the latter or of the cylindrical roller bearing ( 4 , 5 ) in question is connected to a single axial projection ( 19 , 28 ) which, with axial play and engaging in a guide recess ( 26 ) in the opposite end face ( 17 and 18 ), between two side faces ( 27 ) de r guide recess ( 26 ) is slidably arranged in the radial direction. 2. Rolling bearing arrangement according to claim 1, characterized in that the two side surfaces ( 27 ) of the guide recess ( 26 ) of the end face ( 17 or 18 ) of the inner ring ( 7 , 8 ) of the cylindrical roller bearing ( 4 or 5 ) or the angular contact roller bearing ( 3 ) are arranged running parallel to one another in the radial direction. 3. Rolling arrangement according to claim 1 or 2, characterized in that the two side surfaces ( 27 ) of the guide recess ( 26 ) of the end face ( 17 or 18 ) of the inner ring ( 7 , 8 or 11 ) of the cylindrical roller bearing ( 4 , 5 ) or . of the angular contact roller bearing ( 3 ) are each arranged lying in a longitudinal plane. 4. Rolling bearing arrangement according to claim 1, 2 or 3, characterized in that the projection ( 28 ) on the side surfaces ( 27 ) of the guide recess ( 26 ) of the end face ( 17 or 18 ) of the inner ring ( 7 , 8 or 11 ) of the Cylindrical roller bearing ( 4 , 5 ) or the angular roller bearing ( 3 ) has sliding, convexly curved boundary surfaces ( 32 ). 5. Rolling bearing arrangement according to one of the preceding claims, characterized in that the projection with the end face ( 17 or 18 ) of the cylindrical roller bearing ( 4 , 5 ) or the angular contact roller bearing ( 3 ) is integrally connected. 6. Rolling arrangement according to one of claims 1 to 4, characterized in that the projection by a with the end face ( 17 ) of the inner ring ( 7 , 8 ) of the cylindrical roller bearing ( 4 , 5 ) or the angular contact bearing ( 3 ) firmly connected fitting ( 19 , 28 ) is formed. 7. Rolling bearing arrangement according to claim 6, characterized in that the adapter ( 19 , 28 ) in a holding recess ( 20 ) in the end face ( 17 or 18 ) of the inner ring ( 7 , 8 ) of the cylindrical roller bearing ( 4 , 5 ) or Angular contact bearing ( 3 ) is positively attached. 8. Rolling bearing arrangement according to claim 6 or 7, characterized in that the fitting ( 19 , 28 ) by means of one or more, each in a threaded hole ( 24 ) of the end face ( 17 or 18 ) of the cylindrical roller bearing ( 4 , 5 ) or Angular contact bearing ( 3 ) screw-in cap screws ( 23 ) is attached to the end face ( 17 or 18 ). 9. Rolling arrangement according to one of the preceding claims, characterized in that each angular roller bearing ( 3 ) is designed as a tapered roller bearing effective in both axial directions, the inner ring ( 11 ) only on one of its two sides by the projection ( 19 , 28 ) with an adjacent one Inner ring ( 7 ) of the cylindrical roller bearing ( 4 ) is rotatably connected. 10. Rolling arrangement according to one of the preceding claims, characterized in that the inner ring ( 11 or 7 , 8 ) of each angular roller bearing ( 3 ) and / or each cylindrical roller bearing ( 4 , 5 ) with lubricant, for. B. graphite or molybdenum disulfide, filled troughs on one or both end faces ( 16 , 17 , 18 ).