DE3239305A1 - Axial bearing support - Google Patents

Abstract

The axial bearing support has the object of compensating automatically for length differences of machine parts (e.g. a transmission shaft in the housing) moving relative to one another resulting from heating in use or different materials, without significantly altering the axial compression stresses on the bearing and hence its axial clearance thereby. This object is achieved by both such a material composition and by a suitably pressure-resistant design of a supporting ring in a manner known per se, which expands faster and approximately only just as far as the part (e.g. the housing) which expands the most, the supporting ring in the mounted state not significantly yielding to the prescribed axial compression stresses of the bearing. In this way, both excessively hard running and excessive play in the bearing are avoided and the screws and housing cross-sections causing the prestressing are largely destressed. The life of such machines can be greatly improved using these cost-effective means, despite increased loads.

Description

The invention relates to an axial bearing support which

one intended to keep the axial clearance in the bearing constant Has support ring.

Such support rings, with the task of tolerance deviations and misalignments etc. to compensate are known per se. For example, DE-GM 74 09 971 has a support ring made of elastically deformable material, which by the axial preload in a bearing housing is compressible so far that it, without the cheapest bearing can affect the air, compensate for dimensional errors.

This means that this support ring must be soft enough to prevent

larger distances between the bearing and the housing due to the corresponding To bridge change of its spring travel. However, if such distances are very large , the axial compressive stress can decrease so that the axial fixation of the Bearing halves is no longer guaranteed.

If there are differences in elongation between the housing and the shaft, e.g. B. by different materials or temperatures of the same, this could result in this Clearly change the bearing clearance compared to the installation state. This can cause bearing damage and / or lead to higher energy consumption.

This problem is particularly common with high-performance gearboxes before, in which a considerable length is still influenced by a light metal housing and high operating temperatures.

The object of the invention according to claim 1 is therefore to provide an axial bearing support to create which even with considerable differences in elongation (e.g. due to the material pairing Aluminum for the housing and steel for the shaft) within the entire operating temperature range no such significant changes in terms of axial clearance and axial preload brings that compared to the assembly setting by the operating heating large Deviations occur.

The solution is through the features of the label of claim 1 achieved in that the support ring does not have a purely resilient function, which would lead to variable bearing forces, but one, the axial preload Characteristics that are kept constant as far as possible even when the plant warms up will. Under the influence of the respective intrinsic temperature, the resulting Increase in the difference in elongation while avoiding an increase in the axial clearance with a comparable pressure-resistant and growing or shrinking material bridge are closed so that they are pressure-tight that also the maintenance of the optimal internal clearance required axial preload from the assembly state in all operating phases as far as possible remains the same. This means that there is neither jamming nor loosening of the bearing elements possible with the disadvantages to be expected.

There is also the advantage that the bias is already in The installation state must not be greater than just necessary. Screws and the housing part are less stressed because there is no voltage drop must be prevented by excess tension, as is the case with only elastic Support ring behavior would be the case.

Further developments of the invention are described in the subclaims.

According to claim 2 it is achieved that the thermal expansion behavior of the Support ring by selecting suitable membrane filling substances (e.g. oil / wax etc.) very precisely to the expansion or

Contraction behavior of the respective construction, material pairing and heating areas is adjustable. It is advantageous that the knowledge of the expansion behavior in such thermal bellows from steam traps and the like Valves are known per se and therefore the production technology is available.

According to claim 3 it is achieved that even with tight installation conditions and large bearing forces, no increased bearing pressure is necessary and (e.g. for large series) the invention with inexpensive, permanently set support ring material composition is particularly inexpensive to use.

According to claim 4 it is achieved that the support ring the possibly.

different axial bearing diameters with minimal material requirements adapted and also partially radially in appropriately prepared design clearances can be fitted.

According to claim 5 it is achieved that not (z. B. by radial clamping effects or adhesive processes) the support ring grows with it or

Shrinkage of the housing or the shaft is prevented because it grows with it the support ring face fixed on the most stretched machine element then the any obstructive radial clamping can be overcome even more safely.

With claim 6, the effect is improved with the same space requirement.

The invention is described using an exemplary embodiment.

Fig. 1 shows a longitudinal section through one on both sides with one according to the invention Support ring locked axial cone bearing.

Fig. 2 shows an unimportant stretching length scheme for the bearing of Fig. 1.

In Fig. 1, the shaft 1 is encompassed by the housing 2 and therein via the Axial roller bearings 3 supported. The axial force component of the bearing 3 is the Bearing outer ring 4 out of the housing 2, but the bearing inner ring 5 in the direction the center of the housing 2 is sheared because the rolling elements here are tapered rollers 6 with the outside of the housing 2 tapering cone. The case 2 is releasable with one of the bearing 3 flanged on the outside Bearing cap 7 connected, in which the gap between housing 2 and shaft 1 by an elastic Seal 8 is kept leak-proof closed. Between bearing 3 and bearing cover 7 is a particularly expandable according to the principle of a "corrugated pipe compensator" designed support ring 9a installed clamping, without against rolling elements 6 or inner bearing ring 5 to trigger.

On its opposite side in an annular groove of the shaft 1 is a full cross-sectional ring made of plastic support ring 9b let in so that only the one at the same time rotating bearing ring initiates the preload force and no relative rotation on the Support ring 9b takes place.

The end face of the external support ring facing the bearing cover 7 9a also has a holder 10 which engages axially fixedly on the bearing cover 7 is. You can either from a, as shown in the drawing, locking connection, or consist of screws, rivets, etc.

The hardness of the support rings 9a, 9b and their expansion behavior is according to of the invention either via the liquid mixture 11 in the distance-compensating Support ring 9a or via the composition of the plastic material in the support ring 9b can be precisely defined.

Care is taken that the support ring 9 under the action of Operating temperature definitely at least faster than that which is strongest stretching machine element (e.g. the housing) stretches.

The function of the support ring is shown in FIG.

The KO and LO pretensioned to the same initial length during assembly, Differences in elongation relative to one another, based on a common support base 0, im Machine elements 1 and 2 (shaft 1 and housing 2) and also the in their final state with their operating lengths Kw and Lw which arise after heating Differences in length are clearly visible.

Part 1 (made of steel, for example) with a lower coefficient of thermal expansion (here shaft 1) only grows by a maximum of K, the other (e.g. made of aluminum) manufactured part 2 with higher coefficient of thermal expansion (here however, the housing 2) grows considerably more, namely by the dimension # L. It also grows but also the one placed in the camp, under the same bias according to the invention Support ring 9 also with the initial length SO and finally decreases under the influence of heat the measure @ L ~ beso = Sw. This changes the compressibility of the ring 9 at most insignificant, so that the preload force with which the bearing 3 is set to optimal internal clearance, both when heating and when cooling can stay the same. For this purpose, at least the one resting against the support ring 9 is in each case Bearing ring 4 or 5 also somewhat axially displaceable under the stretching force of the support ring 9 opposite its seat in the housing 2 or on the shaft 1.

The bracket 10 anchors the stronger growing element (see Housing 2) with the end face of the support ring 2 resting there in such a way that this in the direction of change in length also then drawn with the assistance of the stretching forces can become radial (e.g. due to abrasion particles or oil deposits) Anti-lock effects should cease that can no longer be overcome by the support ring alone can be.

The invention is of course also applicable by subdivision the or the support rings 9a and 9b in individual segments or pressure pieces, which then can also be partially inserted radially into the spaces. Also must a support ring does not always have to be present on both sides of a bearing. Meanwhile, would have to for machines with several elements that experience differences in elongation (e.g. multi-shaft gears) all bearings have support rings with the same effect.

Furthermore, the support ring 9 can also have a wide variety of shapes or forms. Obtain cross-sections without having to deviate from the principle of the invention. So Instead of a rectangular cross-section, an oval ring cross-section can also be used, whose lower height SO in the assembled state relates to the operational support height Sw, in particular by reshaping the oval into a circle due to the increased and a uniformly spreading internal pressure is established in the ring. This type would have the advantage of even lower costs with a very high preload load capacity, but cannot bridge larger differences in axial expansion as reliably as the execution of the support ring, which functions similarly to the known thermal bellows after version 9a.

As an example of the advantages of the axial bearing support according to the invention let it be applied to an approx. 500 mm long gear when heated to 1000 C considered in more detail: The shaft (made of steel) would be approx.0.56 mm from the housing (from Alu) would grow by approx. 1.19 mm. The excess elongation #S would thus be 0.63 mm. To bridge this, a support ring height was required: a) with a spindle oil containing thermal bellows 8.6 mm or b) with a ring made of (R) ULTRADUR B4500 a Height of 42.3 mm.

In practice, these values are experimentally optimized surcharges z. B. because of decreasing shear modulus values or the like.

added.

The cross-sectional shape of the support ring is preferably such that the expansion pressure increases in the axial direction when heated, such as z. B. with oval or lens-shaped squeezed tube. This is going to be even under Internal pressure under recovery in a pipe with a circular cross-section stronger Stretch in terms of height and hardly change in terms of circumference. If the increase in length of a single Such a pipe ring is not enough for longer machines, several stack them on top of each other.

When the size of the machine and its structural characteristics justify it it enables, of course, a controllable heater can also be applied to the support ring without deviating from the principle of the invention.

Reference number 1 shaft 2 housing 3 axial roller bearing 4 outer ring of FIG 5 inner ring of 3 6 rolling elements 7 bearing cover 8 seal 9a support ring (as diaphragm), z. B. against housing 9b support ring (as a plastic ring), for. B. against shaft 10 bracket from 9a 11 Contents of the support ring (e.g. wax) L Longer machine element (e.g. Housing 2) Lo initial length when mounting L Lw operating length below maximum temperature from L bB Length increase from L at Lw K Machine element remaining shorter (e.g. shaft 1) Ko initial length when installing K Kw operating length below maximum temperature from K #K increase in length from K at Kw So support ring height during assembly (#S: increase in length from So. at Sw) Sw support ring height below maximum temperature of L and K 0 support base in the event of a change in length (e.g. center of the machine) Blank page

Claims (6)

Axial bearing support claims 1. Axial bearing support, for in operation Machine elements that experience differences in elongation and are relatively movable in relation to one another (e.g. shaft 1 in a housing 2), with axially loaded roller bearing (3), of which at least one ring (4 or 5) over a support ring (9) to keep the Bearing play in the bearing (3) against one of the machine elements (1 or 2) against it Contraction direction is supported, characterized in that a) that the support ring (9) compared to a first of the two machine elements (e.g. shaft 1), which is subject to smaller elongations (K), an increased axial coefficient of thermal expansion has, b) the heating of which is carried out in such a way that an operating temperature occurs adjusting excess elongation (Sw) of the second, subject to greater elongation (#L) Machine element (e.g. housing 2) solely through the support ring that expands at the same time (9) with a temperature that roughly corresponds to the installation state for all operating temperatures Axial compressive stress is compensated, c) the dimensional stability of the support ring Even in terms of operating heat, it is of a similar magnitude as in assembly lies. 2. Support according to claim 1, characterized in that g e k e n n -z e i c h n e t that the support ring (9) has a membrane body (9a) with hermetically enclosed therein Expansion medium (e.g. oil / wax etc.). 3. Support according to claim 1, characterized in that g e k e n n -z e i c h n e t that the support ring (9) still has its initial compressive strength at operating heat retaining plastic (9b). 4. Support according to one of claims 1 to 3, characterized g e k e n n z e i c h n e t that the support ring (9) is composed of several segments is. 5. Support according to one of claims 1 to 4, characterized g e k e n n z e i c h n e t that the support ring (9) in the second, a greater thermal expansion subject machine part (e.g. housing 2) is held on one end face and this end face when heated compared to the less expanding machine part (e.g. shaft 1) in the axial direction away from the bearing (3) even if there is a radial clamping forces can be taken along. 6. Support according to one of claims 1 to 5, characterized g e k e n n z e i c h n e t that the support ring (9) has a cross section whose thermal expansion capacity is larger in the axial direction than in the circumferential direction.