DD228899A1 - WAFER BEARING RECEIVING DEVICE WITH INTERNAL RING DRIVE AND RADIAL LOADING GENERATION, ESPECIALLY FOR GERAE CHECK DEVICES - Google Patents

Abstract

The invention provides a device which allows the inclusion of rolling bearings for the purpose of Geraeuschpruefung under radial load or similar tests (eg., Frictional torque, lubrication behavior) without the need to date as mandrels, which produced with much effort and expense had to be and which are subject to high wear. The inclusion of the rolling bearing and the drive of the inner ring without mandrel is thus virtually wear-free, and concentricity error of the drive spindle and the runway for drilling the inner ring have no influence on the test result of the vibration or other tests. The automation of test facilities for the above-mentioned tests is greatly facilitated. Fig. 1

Description

a) Title of the invention

Wälzlageraufnahmevorrichtting with inner ring drive and radial load generation, especially for Geräuschprüfe inrichtung en

b) Field of application of the invention

The invention relates to a device for receiving in particular of rolling bearings, wherein the inner ring is made to rotate and the outer ring is stationary. The device is preferably used in testing devices and machines for running noise testing of rolling bearings which have to be tested under radial load.

c) Characteristic of the known technical solutions

In the Fälzlagerfertigung, especially in the production of bearings with increased runnability, the running noise is tested with special test equipment or testing machines · 'For this purpose, the rolling bearing is taken in all known solutions with the bore of the inner ring on a receiving and driving mandrel and the inner ring pressed over the outer ring and the rolling elements against the abutment collar of the arbor. The structure-borne sound determination is carried out by means of a vibration pickup by this is placed radially with a certain test force on the outer ring. It is necessary that the inner ring is received with a very high concentricity on the mandrel. Furthermore, it is important that the inner ring has the necessary test rotation through the rotating mandrel.

which must be guaranteed even during the actual test period (that is, no slippage occurs between the mandrel and the inner ring).

Known are devices in which the test bearings are pushed manually or automatically onto the receiving mandrel and the required loading forces are applied. "

Practice has shown that such devices have some disadvantages. It is Z. B. very difficult and associated with high costs to achieve the necessary high running accuracy of the mandrel and to obtain a sufficiently long service life. The bearing of the drive spindle and the mandrel must be manufactured with very high precision. The same applies to all parts which are necessary when changing over the testing devices from one to another type of bearing (change of the receiving mandrel). Sin further Hachteil is that the holes of the inner rings of the bearings and the mandrel with the bearing seat have manufacturing tolerances and therefore no perfect concentricity of the inner rings can be guaranteed * These factors have significant! Lachteile on the test result and distort it in many cases.

As a special part, it has further been found that the wear of the arbor is very large in the current clamping method. This phenomenon is due to the fact that when sliding the bearing on the rotating mandrel of the inner ring is initially at rest and must be accelerated only with the contact with the mandrel. A high wear of the seat of the mandrel and a replacement of the same in relatively short time intervals is necessary, otherwise the inspection accuracy suffers. Technologically, therefore, very high demands are placed on the production of the mandrels and the drive spindle bearing with regard to accuracy. The result is high manufacturing costs and production times.

The disadvantages of the latter point occur especially. for "larger" test bearings (100 to 200 mm diameter). The mass to be accelerated of the inner ring is here so großi that the "slip time" until the complete achievement of the "test speed is so high that the.Abnutzung the receiving mandrels s is no longer acceptable. In these cases, the drive spindle must be brought to a standstill for the purpose of sliding the bearing before each bearing test, thus reducing the performance of the test equipment and making the test process uneconomical.

In order to counteract the deficiencies that arise from the tolerances of the bore of the inner rings and the seat of the mandrel and the wear of the same, special measures are required and known. Such are z. B. Replacement of the mandrels in accordance with experience periods, upchambers and Heuschleifen, use of Spreizdornen slotted with inherent resilience, cone or pressure medium spreading · 'All these known solutions, however, require a lot of time and money and leads.not always to the desired success (especially expanding mandrels )

It is also known that with radial air testing devices the outer ring of a roller bearing is placed on a support prism and the inner ring is driven in .the bore with a radially pressed friction disk, eg made of felt. However, this solution for this special case is for the Applying a Aziallast on the rolling bearing not and also only for "low" speeds, which are below the test speed, suitable · * In the known solutions for Yfälzlageraufnahmevorrichtungen and the drive of the inner ring for the noise test prevails the abandonment of radial load, the over the outer ring is applied.

In the known solutions, the stripping of the inner ring from the mandrel is difficult, especially in cylindrical roller bearings with inner ring without rims. Bearings with only one board on the inner ring must be fed directionally, so that the board is always on the same side. This requires additional Riehteinrichtungen.

d) Object of the invention

The aim of the invention is to eliminate the identified deficiencies and disadvantages, in particular to guarantee the reliability of the devices and machines and to provide a virtually wear-free recording and a wear-free drive of the inner ring, with the proviso that the inaccuracy of the drive spindle has no influence on the Test result has.

e) Presentation of the essence of the invention

The technical problem to be solved by the invention is that preferably for running noise testing of rolling bearings under radial load recording of rolling bearings is provided with drive the inner rings, which requires no mandrels with very high precision, in the concentricity inaccuracies of the drive spindle, the test results do not affect the automation of the: Testing process can be achieved significantly more economical and at the same time a radial load is generated »

According to the invention this is achieved in that a running noise to be tested roller bearing is no longer pushed as before on a very accurate rotating mandrel, but that the bearing with the outer ring on solid support posts (the outer diameter of the bearing accordingly) is centered ·

The bearing is axially positioned with little play on the end faces of the outer ring, on the support posts with a suitable spread angle OC , which is selectable in a conventional manner, on. The inner ring of the bearing is clamped at the end faces between the annular end face of a driven with the Prüfdrehzahl contact disk and the likewise annular end face of a follower thrust washer with a pressing force 2nd The circular ring widths are kept much narrower than those of the front side surfaces of the inner rings, so that they are also at axial offset (to generate the radial load)

do not reach beyond the connection dimensions (edge rounding and bevel) of the flat end faces of the inner rings. ' Thus, the flatness of the contact surfaces is maintained even with wear (no run-in traces). Anlagescheibe and thrust washer are axially adjustable so that the outer ring of the bearing after clamping the inner ring to the axial pre-positioning axial guide members (guide plates) is not applied or ' these touched only on one side without investment force. The axial guidance has only so much clearance for the bearing width that the bearing can be introduced well (rolling in) and the opening travel s remains minimal. In cylindrical roller bearings with axially displaceable inner ring this is almost brought to its alignment with its end faces to the end faces of the outer ring.

The axes of the drive shaft with contact washer and the. Pressure disc are horizontal and aligned with each other. The axis of the bearing is radially displaceable by adjusting the support supports in a conventional manner (coordinates X - Y), that by the friction on the end faces of the inner ring, which is formed by a radial, acting in the direction of the bisector of the spread angle oC force component arises, causing the bearing a radial load. Receives Fp.

The thrust washer is mounted on its bearing shaft so that it can make something wrong by elastic support and thus the influence of non-parallelism of the inner ring end faces is compensated.

The housing of the bearing shaft is held at its end facing away from the thrust washer in a joint element (ball joint, diaphragm, etc.) and centered in the vicinity of the pressure washer by an elastic support in an outer housing, so that the axis is aligned with the axis of the drive shaft. ·

After clamping (clamping) of the inner ring between the driven bearing plate and the follower thrust washer with the pressing force F. The axis of the bearing shaft leads the

Thrust washer due to the axial offset with the coordinates X-Y to the roller bearing axis in the plane of the end face of the end faces inner ring - pressure plate from a circular motion and the axis of the bearing shaft thus describes a cone whose tip is located in the center of the joint element. As a result, there is no radial force acting on the inner ring, which counteracts the force component generated on the contact disk.

It is of course also possible according to the invention to support the bearing shaft of the thrust washer in a rigid, aligned manner with the drive shaft and to drive it synchronously with the drive shaft, whereby radial force components would be generated in the same direction on both end faces of the inner ring. However, the effort is estimated to be higher compared to the previously described solution.

Advantages over previously known solutions:

- The drive spindle is designed without mandrel holder for the inner ring, whereby the running inaccuracies of the same have no influence on the test result. Also, running inaccuracies between the runway and bore of the inner ring have no influence.

- By eliminating the mandrel a secure puncture of the rotation of the inner ring is ensured.

- The generation of radial load on the bearings on, the inner ring is possible without additional facilities.

- The possibilities for the automation of the feed and removal of rolling bearings are significantly improved.

- Purely the maintenance of the test equipment and machines are saved considerable costs by eliminating the mandrels and their preparation for wear.

- It is no shutdown of the drive spindle required because virtually no wear of the drive elements for the inner ring occurs, resulting in a simplified control of the test equipment or machines.

f) embodiment

The invention will be explained in more detail below using an exemplary embodiment.

Show it:

Pig. 1 is a longitudinal section of the device; Fig. 2 is a simplified radial section of the device with representation of the axial offset Σ - Y.

The device consists of rotating at test speed drive shaft 1 with attached washer 2, support posts 3, on which the test bearing with the outer ring 5 under the spread angle oc 8 rests, the follower thrust washer 4, the axially displaceable with the opening s 13 »Presses the inner ring 6 with the pressing force F. 9 against the washer 2. This gives the inner ring 6 the test speed and is due to the axial offset XY relative to the axis of the drive shaft 1 via the rolling body 7 radially pressed onto the outer ring 5, which rests on the support posts 3, whereby the radial load? 2 1 is formed (Pig. 2) .:

Furthermore is. from Pig. 1 that the bearing shaft of the pressure plate 4 is held with the housing at the "rear" end with a joint element formed as a ball joint 11 and that the housing against an outer housing radially and the thrust washer 4 axially against the receptacle on the bearing shaft by elastic supports 12th , in the example designed as rubber rings with appropriate elasticity, centered or held *

For axial Pühr and pre-positioning of the bearing on the outer ring 5 serve axial guide parts 14 »have so much game Lag.erbreite that with retracted thrust washer 4 trouble-free insertion and removal of the bearings by feeders or manually guaranteed.

The specific advantages of the embodiment are the relatively simple construction and manufacturability

the device and in the expected high reliability and freedom from wear.

Claims (5)

Invention claim: 1. Rolling bearing receiving device with inner ring drive and radial load generation, especially for noise testing devices with radial load of rolling bearings using known support posts for the outer ring on which the roller bearing is centered in the radial direction and thereby the axis to the axes of a driven contact disk in a known manner with coordinates XY is offset, characterized in that at a rotating with Prüfdrehzahl drive shaft (1) at the head end a bearing plate (2) provided at right angles to the axis of the drive shaft (1) lying annular flat surface, with respect to this an equally formed axially by a pressing force i ¹ ( 9) about the opening travel s (13) movable follower or synchronously with the drive shaft (1) driven pressure disc (4) between which the inner ring (6) of the bearing, axial guide members (14), between which the outer ring (5) of Bearing is located, and radial to the axle s of the drive disc (2) and the thrust washer (4) with the coordinates XY adjustable support supports (3) on which the outer ring (5) rests, and that between the contact disc (2) and the thrust washer (4) to the End sides of the inner ring (6) with the pressing force P ₁ (9) clamped bearing an axial offset XY (Fig. 2) with respect to the axes of the contact disk (2) and the pressure slide be (4) in a conventional manner · 2. Device according to item 1, characterized in that the bearing housing of the bearing shaft of the thrust washer (4) on the thrust washer remote end held in a ball joint or similar joint element (11) and the axis of the bearing shaft in each radial direction at the other end, on the the thrust washer (4) is arranged, is deflectable, 3. Device according to the points 1. and 2., characterized in that the pressure plate (4) in the axial direction and the bearing housing for the bearing shaft of the thrust washer (4) are provided in the radial direction with elastic supports (12) of different elasticity. 4. Device according to the points 1., 2. and 3 · », characterized in that the at the end faces of the inner ring (6) of the Fälzlagers under the pressing force F ₁ (9) adjacent annular flat surfaces of the contact disk (2) and the pressure plate ( 4) in their annulus width. one of the terminal dimensions of the plan portion of the end faces of the inner ring ("6) to the edge rounding and chamfer given circular ring width of the same and by the axis offset of the inner ring (6) Σ - 1 conditional / / ertes is smaller than the circular ring der.Firnseiten the inner ring ( 6) in the area of the connection dimensions · 5. Gate direction according to the points 1 ·, 2, 3 · and 4 · »characterized in that one by displacement of the axis of the bearing with the coordinates XY with respect to the axis of the bearing disc (2) and the thrust washer (4), if the latter not radially deflectable mounted and synchronously with the contact disk (2) is driven, due to frictional forces on the end faces of the inner ring (6) generated radial load F ₂ (10) in the direction of the bisector of the spread angle oc (8) of the support posts (3) on the Outer ring (5) directed. For this 2 sheets of drawings