DE102009037392A1 - Antifriction bearing arrangement for mounting rotating shaft opposite to e.g. machine table, in round table device of machine tool, has bearing connected parallel to another bearing by pretensioning unit in main load effective direction - Google Patents

Abstract

The arrangement has an antifriction bearing (3) i.e. angular ball bearing, arranged between a rotating shaft (4) and a fixed supporting construction (1). Another antifriction bearing (5) i.e. radial bearing, is connected parallel to the former antifriction bearing by a pretensioning unit (6) i.e. pretensioning spring, in a main load effective direction such that the former antifriction bearing is unloaded, where the former bearing has larger diameter than the latter bearing in the load effective direction.

Description

Field of the invention

The The present invention relates to a bearing arrangement for axial and / or Radial bearing of a rotating shaft against a fixed Support structure between which at least one rolling bearing is arranged.

The Field of application of the present invention extends primarily on rolling bearings rotating machine parts, such as Main spindles of lathes or rotary tables for machine tools. Conventional bearings available as catalog are limit values in terms of carrying capacity and maximum rotational speed. At over-high Loads is the use of standard rolling bearings therefore not meaningful; it has to resort to a multiple arrangement if an application-specific rolling bearing design out of the question

From the DE 10 2005 024 004 A1 is a generic rolling bearing assembly, which is provided as a thrust bearing primarily for supporting a turntable of a machine tool. The rolling bearing assembly comprises a rolling bearing which acts predominantly as a thrust bearing for pivotally mounting a turntable in relation to a stationary support structure, wherein a magnetic device acting in parallel to the rolling bearing between the turntable and supporting structure is provided for generating a compensating force substantially opposite to that produced by the weight of the turntable the rolling bearing introduced axial force acts. This results in a force compensation, which increases the carrying capacity of the bearing.

The resulting, actually acting on the rolling bearing Power can thus to a large extent, depending on the design the device, be compensated. This makes it possible smaller bearings at the same time sufficiently long To use life, which also work with high continuous speeds can.

Though does not need complicated by this technical solution Hydrostatic bearings with correspondingly higher load capacity be used, but cause the necessary magnetic elements, preferably permanent magnets, also a rather high component and assembly costs. Moreover, this technical solution is for Use cases where ferro-metallic shavings arise, less suitable, as this is due to the magnetic field on the machine table stick and are difficult to remove.

in the well-known prior art is alternatively to the above explained magnetic force compensation for reduction the load of a rolling bearing and a multiple arrangement used, in particular, to increase the bearing capacity. In addition, there are also multi-row roller bearings in standard designs available. However, this solution alternative causes a larger space to accommodate the multiple or multi-row rolling bearings and not all bearing parameters can be solved thereby enlarge. This reduces, for example the maximum permissible rotational speed for multi-row Roller bearings.

It is therefore the object of the present invention, a rolling bearing assembly to create, which with little technical effort and high resilience suitable for a wide range of applications.

The Task is based on a rolling bearing assembly according to the The preamble of claim 1 in conjunction with its characterizing features solved. The following dependent claims give advantageous developments of the invention again.

The The invention includes the technical teaching that to increase the load capacity of the storage a separate, second rolling bearing is provided, the so in the main load acting over at least one biasing means, in particular a biasing spring, connected in parallel with the first rolling bearing is that a Relief of the first rolling bearing takes place.

alternative or in addition to a biasing spring, for example Also, a hydraulic cylinder can be used as a biasing means. Both the biasing spring and the hydraulic cylinder or a Hydraulic pads are used as force-controlled biasing means in the Rolling arrangement according to the invention used.

The advantage of the solution according to the invention is, in particular, that a bearing relief is realized by the use of simple technical components. The separate second rolling bearing takes on as a kind of auxiliary bearing by the spring or fluid-technically generated bias on a part of the load of the mainly loaded first rolling bearing. By so far biased auxiliary bearing so the main bearing is relieved. The solution according to the invention is particularly suitable for applications with one-sided bearing load. Due to the spring adjustment or hydraulic or pneumatic bias, it is not absolutely necessary that the auxiliary bearing has the same accuracy as the main bearing, since any inaccuracies by the at least one Vor be compensated. As a result, the solution according to the invention can be implemented with relatively low production engineering and financial expense.

Should in a certain application the main load direction of action on the main, first bearing axial, So be in the axial direction of the shaft to be stored, it should first rolling bearing preferably as a standard be formed pure thrust bearing. Also for the selection the matching parallel to switching second rolling bearing offers a thrust bearing, but not the same with must be the first rolling bearing. For example, that can second rolling bearing in terms of its load capacity be more resilient than the first rolling bearing, so that the second rolling bearing according to the solution according to the invention the main part can absorb the main load and thus the first rolling bearing relieved. But it can also be the other way around, so that the first rolling bearing higher load bearing capacity than the second rolling bearing is.

A Axial Hauptbelastungswirkrichtung occurs for example in a Rotary table device on, whose shaft of the rotary table with a Rolling bearing assembly is rotatably mounted, wherein the support structure for the rotary table is a machine table or the like.

at an application with radial main load acting direction should the first rolling bearing, however, designed as a standardized radial bearing be. The parallel thereto second rolling bearing can be used as a spring or by pressure be formed of a fluid loaded radial bearing.

One exemplary application for such a radial main load acting direction is for example a machine tool whose work spindle for Drive a tool or workpiece rotating opposite a machine chassis is mounted as a support structure.

Naturally It is also conceivable, instead of rolling bearings with exclusive or predominantly axial load - such as thrust ball bearings, Axial needle bearing, four - point bearing or roller bearing for exclusive or predominant Radial load - such as cylindrical roller bearings, needle roller bearings - too Rolling Bearings for Radial and Axial Loads - so-called Angular contact bearings or bearings for combined loads - to be used. angular contact bearings can be ball bearings, angular contact ball bearings, tapered roller bearings, Kreuzkegel- and cross-cylindrical roller bearings, self-aligning ball bearings and the like.

According to one the measure improving the invention is proposed that in the parallel power flow through the second rolling bearing arranged with biasing means at least one damping element is. Thus, the damping element is in series with the second Rolling and the biasing spring in the parallel power flow connected. The damping element serves a reduction the tendency to oscillate in a row resonance.

in the Trap of a thrust bearing assembly is according to a other proposed measure of the invention, the first rolling bearing with such a large diameter to measure that this surrounds the second rolling bearing. By the larger diameter of the first rolling bearing can this be a bearing with higher load capacity be selected and a significant, but not the largest proportion of the load is due to the interior, second Rolling bearing with upstream or downstream Nachspannfeder compensated. But it is also conceivable that for the second Rolling bearing a bearing with a higher load capacity is chosen, so the largest share the load is absorbed by the second rolling bearing. In addition, the second rolling bearing around the first rolling bearings are arranged around, if special constructional constraints require this.

Further, The measures improving the invention will be described below together with the description of two embodiments illustrated in more detail with reference to the figures. It shows:

1 a schematic side view of a rotary table device with a rolling bearing assembly for the predominant axial bearing of a rotary table and load compensation means,

2 a schematic side view of a machine tool with a predominantly radially mounted work spindle and load compensation means, and

3 a front view of the radial bearing of the work spindle after 2 ,

According to 1 there is a rotary table device schematically shown here in partial section essentially of a support structure 1 , which is part - a not shown - machine table on which a rotary table 2 via a first rolling bearing 3 is mounted rotating. The first rolling bearing 3 is designed in the manner of a double-row angular contact ball bearing, which is mainly loaded axially. The main axial load acting direction becomes substantially the weight of the massive rotary table 2 and the arranged thereon - not shown - workpiece and its processing causes. The first rolling bearing 3 Nonetheless, it can also absorb a radial load. A wave 4 of the round piece 2 is via a screw connection with the bearing inner ring of the rolling bearing 3 connected, whereas its outer bearing ring with a screw on the part of the support structure 1 is flanged. To increase the overall bearing capacity, a separate - here only schematically illustrated - second rolling bearing 5 provided in the axial main load acting direction of this embodiment over a plurality of circumferentially arranged biasing means 6 namely, biasing springs, parallel to the first rolling bearing 3 is switched.

This results in a significant relief of the first rolling bearing 3 , The second rolling bearing 5 is a pure thrust bearing in this embodiment. In addition, in the parallel power flow through the second rolling bearing 5 with downstream biasing spring 6 a damping element 7 provided, which has the shape of a ring body, which in a corresponding recess on the part of the support structure 1 is inserted. In the embodiment according to 2 is schematically a work spindle 8th a - not shown - machine tool shown, which has a few of the first rolling bearings 3a ' . 3b ' opposite a stationary support structure 1' is rotatably mounted. To relieve this predominantly radial bearing is a separate, second roller bearing 5 ' provided in the prevailing here radial Hauptbelastungswirkrichtung over a plurality of around the circumference arranged biasing springs 6 parallel to the arrangement of the first rolling bearings 3a ' . 3b ' is switched.

The 3 The front view in section AA represents the above-described bearing arrangement for the work spindle of the machine tool and illustrates the possible distribution of the plurality between the support structure 1' and the work spindle 8th around the second rolling bearing 5 ' arranged around biasing springs 6 ' In their position are the biasing springs 6 ' such around the circumference of the work spindle 8th distributed that an effective relief of - not recognizable here - first rolling bearing 3a ' and 3b ' takes place. In this embodiment, the static weight stress, but also dynamic torsional stresses can be included.

The invention is not limited to the two preferred embodiments described above. On the contrary, modifications are also conceivable which are included in the scope of protection of the following claims. For example, it is also possible to arrange a biasing spring in the power flow on both sides of the respective second rolling bearing and in particular the first roller bearing can also be designed as angular contact bearings or as a bearing for combined loads to make an axial and radial bearing. It is also possible to use the preload springs 6 . 6 ' to replace by hydraulic cylinders, which in a simple manner, a variation of the biasing forces can be realized. The selection of rolling bearings depends on the application-related main load acting direction.

LIST OF REFERENCE NUMBERS

1

supporting structure

2

roundtable

3

first roller bearing

4

wave

5

second roller bearing

6

biasing means

7

damping element

8th

work spindle

QUOTES INCLUDE IN THE DESCRIPTION

This list The documents listed by the applicant have been automated generated and is solely for better information recorded by the reader. The list is not part of the German Patent or utility model application. The DPMA takes over no liability for any errors or omissions.

Cited patent literature

• DE 102005024004 A1 [0003]

Claims (11)

Rolling bearing arrangement for the axial and / or radial support of a rotating shaft ( 4 ) with respect to a fixed support structure ( 1 ) between which a first rolling bearing ( 3 ), characterized in that to increase the bearing capacity a separate, second roller bearing ( 5 ) is provided in such a manner in the main load acting direction via at least one biasing means ( 6 ) parallel to the first rolling bearing ( 3 ), that a relief of the first rolling bearing ( 3 ) takes place. Rolling bearing assembly according to claim 1, characterized in that at axial main load acting direction of the first rolling bearing ( 3 ) is designed as a thrust bearing. Rolling bearing arrangement according to claim 2, characterized in that the second rolling bearing connected in parallel therewith ( 5 ) is designed as a thrust bearing. Rolling bearing arrangement according to claim 1, characterized in that the first rolling bearing ( 3 ) is formed as a radial bearing. Rolling bearing assembly according to claim 4, characterized in that the second rolling bearing connected in parallel therewith ( 5 ) is designed as a spring-loaded radial bearing. Rolling bearing arrangement according to claim 1, characterized in that the first rolling bearing ( 3 ) is an angular bearing for radial and axial load or a bearing for combined loads and by the second rolling bearing ( 5 ) is relieved in the main load direction. Rolling bearing arrangement according to claim 1, characterized in that in the parallel power flow through the second rolling bearing ( 5 ) with upstream or downstream biasing means ( 6 ) at least one damping element ( 7 ) is arranged. Rolling bearing assembly according to claim 1, characterized in that at axial main load acting direction of the first rolling bearing ( 3 ) has a large diameter so far that this is the second rolling bearing ( 5 ) surrounds. Rolling bearing arrangement according to claim 1, characterized in that as prestressing means ( 6 ) is provided a biasing spring. Rotary table device whose shaft ( 4 ) for a rotary table ( 2 ) is rotatably mounted with a rolling bearing assembly according to any one of the preceding claims 1-3, wherein the supporting structure ( 1 ) is a machine table. Machine tool with a work spindle ( 8th ) for driving a tool or workpiece, which is a rolling bearing assembly according to one of the preceding claims 1, 4 and 5 rotatably mounted, wherein the supporting structure ( 1' ) is a machine chassis.

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