DE102010043205B3 - Calibration device for measuring axial air of roll bearing, has lower disk/ring portion including lower support surface facing planar ring-shaped bearing surface, and upper disk/ring portion facing planar annular bearing-area - Google Patents

Abstract

The device (2) has an outer ring part with a cylindrical outer contour including an upper face surface and a lower face surface for extending inward and toward an overlay portion comprising upper and lower annular support surfaces. An inner ring part includes upper and lower planar face surfaces. An upper disk or ring portion of the upper support surface faces planar annular bearing-area connected with the lower face surface. A lower disk or the ring portion includes a lower support surface facing a planar ring-shaped bearing surface.

Description

The invention relates to a calibration standard for the calibration of a device for measuring the axial air of a rolling bearing.

In the manufacture of rolling bearings, the measurement of the exact geometry of the parts of the bearing is essential. An important feature of the bearing in this context is its axial clearance. Depending on the bearing type and bearing design, specified values must be observed for this value, which must be within a defined tolerance band. To measure the clearance, devices are known as in 1 shown and described below.

The bearing to be measured is here taken up in the measuring device and applied against each other directed axial forces between the outer and inner ring of the bearing. The resulting axial displacement of the bearing, which corresponds to the axial clearance, is measured.

A measuring device for measuring the length of a spacer sleeve in a double-row ball bearing discloses the GB 740 819 A , The DE 815 699 B discloses a divided gage. From the US Pat. No. 6,460,423 B1 It is known to determine the preload in a double-row tapered bearing arrangement in that the axial deformation of the bearing assembly is compared with a master bearing arrangement.

Measuring arrangements of this type must be calibrated regularly to ensure their exact work. In particular, it is required that measuring systems for determining the axial clearance of rolling bearings have a correspondingly high accuracy. Therefore, these systems must be regularly calibrated according to specified standards (eg ISO 9001). For calibration, a normal is required, which is usually a defined rolling bearing whose bearing clearance is known.

The calibration standard for the axial internal clearance is regularly introduced into the axial-air measuring system after a recalibration interval stored in a database and calibrated on-site by applying different piston forces (from above and below). Ie. it will u. a. Checks whether the two pistons of the axial-flow measuring system, as usual under the force settings as in the case of the axial air test of rolling bearings, correspond to the axial displacement with alternating load as depicted by the calibration standard.

It is disadvantageous in this connection that the provision and provision of precisely manufactured roller bearings as a calibration standard is relatively complicated and expensive.

The invention is therefore based on the object to provide a calibration standard of the generic type, with an improved and more stable calibration of a device for the axial bearing air measurement is possible.

The solution of this object by the invention is characterized by an outer ring member having a substantially cylindrical outer contour with an upper and lower planar end face, wherein the outer ring member has an axis and wherein the outer ring member has a radially inwardly extending support portion having an upper and a lower annular bearing surface, and an inner ring portion having an upper and a lower planar end surface, wherein the inner ring portion has an upper, the upper face having disc or ring portion and a lower, the lower face having disc or ring portion, both or ring sections are connected to each other via a connecting disc or a connecting ring, wherein the upper disc or ring portion has a the upper bearing surface of the support portion facing flat annular bearing surface, wherein the lower disc or Ringab section having a lower bearing surface of the support portion facing planar annular support surface and wherein the sum of the axis measured distances between the upper support surface of the support portion and the support surface of the upper disc or ring portion and the lower support surface of the support portion and the support surface of the lower discs - or ring portion corresponds to the predetermined value of the air of the calibration standard or the internal clearance.

The extension of the outer ring part in the direction of the axis and the extension of the inner ring part in the direction of the axis are preferably the same size.

The inner ring part is preferably arranged with radial clearance to the outer ring part; The radial clearance between the inner ring part and the outer ring part is preferably between 0.05 and 0.5 mm.

The inner ring part is preferably formed at least two parts for the purpose of mounting, wherein the upper and / or the lower disc or ring portion is attached to the remaining part of the inner ring part. The inner ring part is particularly preferably formed in three parts, wherein the upper and the lower disc or ring portion and the connecting disc or the connecting ring are made as separate parts and connected to each other. The Parts of the inner ring part are preferably connected to each other by means of a screw connection.

The end faces and the bearing surfaces are preferably ground, possibly even honed.

The parts of the calibration standard are preferably made of hardened steel, more preferably made of ball bearing steel 100 Cr 6.

According to the invention, therefore, a calibration standard is used, which consists of an inner and an outer part. The two parts are to be manufactured and calibrated separately by length measurement separately from each other and have a defined axial air in the mounted state. From the dimensions and the known air, the theoretical displacement of the two parts can be calculated under the influence of the axial force.

By experiments using different forces on different axial air measuring systems can be shown that the theoretically calculated axial travel of the two parts coincide with the actual path in Axialluft measuring system. It is possible to determine the reciprocal movement of the pistons and the resulting travel of the inner part relative to the outer part.

Thus, the calibration of the measuring system by means of a reference standard is possible, which has a defined displacement between inner and outer part as an intrinsic value (measured in the SI unit "meter").

In the drawing, an embodiment of the invention is shown. Show it:

1 schematically a device for measuring the axial bearing clearance of a rolling bearing in the form of a deep groove ball bearing,

2 the radial section through a calibration standard for the calibration of the device according to 1 .

3a the radial section through a part of Kablibriernormals according 2 wherein a position is shown in which an inner ring part is relative to an outer ring part in a lowermost position, and

3b the radial section analogous to 3a wherein a position is shown in which the inner ring part is located relative to the outer ring part in an uppermost position.

In 1 is schematically a device 2 represented, with the axial bearing clearance of a rolling bearing 3 can be measured in the form of a deep groove ball bearing. The rolling bearing 3 is with its outer ring 18 between two ring sections 19 and 20 the device 2 taken so that it is fixed in the direction of the axis a. By means of a first stamp 21 and a second stamp 22 can - from here not to be discussed force generating elements - a downward or upward force on the inner ring 23 of the rolling bearing 3 be exercised. The resulting movement or displacement between the inner and outer ring of the bearing in the direction of the axis a is determined by a measuring element 24 detected in the form of a dial gauge. The of the measuring element 24 measured maximum deflection between the end positions when applying the punches 21 respectively. 22 can be achieved, corresponds to the bearing clearance of the bearing 3 ,

To the device 2 To calibrate after a predetermined time is instead of the rolling bearing 3 a calibration standard 1 to use in the device that provides a defined and known measure of the clearance, so that it can be checked whether the device 2 still working within the required accuracy tolerances.

The calibration standard according to the invention 1 is in a preferred embodiment in the 2 and 3 shown.

The calibration standard 1 has an outer ring part 4 having a substantially cylindrical outer contour. It has an upper flat face 5 and a lower flat face 6 , The cylindrical contour of the outer ring part has an axis a. Furthermore, the outer ring part 4 a radially inwardly extending support portion 7 ; this has an upper planar annular bearing surface 8th and a lower level annular bearing surface 9 on.

Furthermore, the calibration standard has 1 an inner ring part 10 , This also has an upper flat end face 11 and a lower flat face 12 , The inner ring part 10 is formed in three parts (also a two-part design is possible), wherein the three parts are connected by (not shown) screw together. The three parts are an upper disc section 13 that the upper end face 11 having; then the inner ring part has 10 a lower disc section 14 that the lower end face 12 having. The two parts 13 . 14 are over a connecting disc 15 connected with each other.

The upper disc section 13 has a flat annular bearing surface 16 , the upper bearing surface 8th of the support section 7 is facing. Meanwhile, the lower disc section has 14 a flat annular bearing surface 17 that the lower bearing surface 9 of the support section 7 is facing.

The sum of the distances L ₁ and L ₂ measured in the direction of the axis a (see 2 ) between the upper bearing surface 8th of the support section 7 and the bearing surface 16 of the upper disc section 13 and the lower bearing surface 9 of the support section 7 and the bearing surface 17 of the lower disc section 13 corresponds exactly to a predetermined value for the air of the calibration standard according to the bearing clearance, with the L in the 3a and 3b is registered.

In these figures is a section of the calibration standard 1 shown enlarged, wherein in the illustration according to 3a the inner ring part 10 relative to the outer ring part 4 in the lowest position while in the illustration according to 3b from the inner ring part 10 the top position is taken. Accordingly, it can be seen that the maximum axial displacement of the inner ring part 10 relative to the outer ring part 4 the bearing clearance is L, with the calibration standard 1 should be specified if the calibration standard 1 instead of the rolling bearing 3 into the device 2 is used to calibrate them.

The axial extent B of the outer ring part 4 and the axial extent b of the inner ring part 10 are the same size.

Between the outer ring part 4 and the inner ring part 10 is a radial game S ago.

The preferred embodiment of the calibration standard proposed according to the invention thus comprises an outer ring part 4 with a cylindrical contour. Radial inside, the outer ring part 4 an annular shoulder (support section 7 ) on. An inner ring part 10 has an inverse outer contour, ie a cylindrical outer contour with an annular recess (outer circumference of the connecting disc 15 ), in which the paragraph (edition section 7 ) intervenes. To ensure the assembly is the inner ring part 10 from at least two parts 13 . 14 . 15 constructed, for example, are screwed. Between the inner ring part 10 and the outer ring part 4 There is a radial clearance S defined size, so that the inner ring part 10 opposite the outer ring part 4 axially displaceable by a force.

The dimensions of the inner ring part 10 and the outer ring part 4 are exactly determinable in a separate state by means of a length measurement. It is thus no longer possible to calibrate the measuring systems for the axial air measurement of a roller bearing by means of a calibration roller bearing, but to use the proposed calibration standard.

LIST OF REFERENCE NUMBERS

1

calibration standard

2

Device for measuring the axial internal clearance

3

Ball or roller bearings

4

Outer ring portion

5

upper face

6

lower end face

7

bearing section

8th

upper support surface

9

lower support surface

10

Inner ring member

11

upper face

12

lower end face

13

Upper disc or ring section

14

lower disc or ring section

15

Connecting disk / connecting ring

16

bearing surface

17

bearing surface

18

outer ring

19

Ring section (clamping ring for the bearing outer ring)

20

Ring section (clamping ring for the bearing outer ring)

21

Punch (acting axially in both directions)

22

Punch (acting axially in both directions)

23

inner ring

24

Measuring element (dial gauge)

a

axis

B

axial extension of the outer ring part

b

axial extension of the inner ring part

L

clearance

L ₁

Distance (partial storage air)

L ₂

Distance (partial storage air)

S

radial play

Claims (10)

Calibration standard ( 1 ) for the calibration of a device ( 2 ) for measuring the axial air (L) of a roller bearing ( 3 ), characterized by an outer ring part ( 4 ) with cylindrical outer contour with an upper ( 5 ) and lower ( 6 ) planar end face, wherein the outer ring part ( 4 ) has an axis (a) and wherein the outer ring part ( 4 ) a radially inwardly extending support portion ( 7 ) having an upper ( 8th ) and a lower ( 9 ) has annular bearing surface, and an inner ring part ( 10 ), which has an upper ( 11 ) and a lower ( 12 ) has a flat end face, wherein the inner ring part ( 10 ) an upper, the upper end face ( 11 ) having disc or ring section ( 13 ) and a lower, the lower end face ( 12 ) having disc or ring section ( 14 ), wherein both disc or ring sections ( 13 . 14 ) via a connecting disk or a connecting ring ( 15 ) are interconnected, wherein the upper disc or ring section ( 13 ) one of the upper bearing surface ( 8th ) of the support section ( 7 ) facing planar annular bearing surface ( 16 ), wherein the lower disc or ring portion ( 14 ) one of the lower bearing surface ( 9 ) of the support section ( 7 ) facing planar annular bearing surface ( 17 ) and wherein the sum of the distances (L ₁ , L ₂ ) measured in the direction of the axis (a) between the upper bearing surface ( 8th ) of the support section ( 7 ) and the bearing surface ( 16 ) of the upper disc or ring section ( 13 ) and the lower support surface ( 9 ) of the support section ( 7 ) and the bearing surface ( 17 ) of the lower disc or ring section ( 13 ) corresponds to a predetermined value (L) of the air of the calibration standard as well as the bearing clearance. Calibration standard according to claim 1, characterized in that the extension (B) of the outer ring part ( 4 ) in the direction of the axis (a) and the extent (b) of the inner ring part ( 10 ) in the direction of the axis (a) are equal. Calibration standard according to claim 1 or 2, characterized in that the inner ring part ( 10 ) with radial clearance to the outer ring part ( 4 ) is arranged. Calibration standard according to claim 3, characterized in that the radial play (S) between the inner ring part ( 10 ) and the outer ring part ( 4 ) is between 0.05 and 0.5 mm. Calibration standard according to one of claims 1 to 4, characterized in that the inner ring part ( 10 ) is formed at least in two parts, wherein the upper and / or the lower disc or ring section ( 13 . 14 ) on the remaining part of the inner ring part ( 10 ) is attached. Calibration standard according to claim 5, characterized in that the inner ring part ( 10 ) is formed in three parts, wherein the upper and the lower disc or ring section ( 13 . 14 ) as well as the connecting disc or the connecting ring ( 15 ) are manufactured as separate parts and connected to each other. Calibration standard according to claim 5 or 6, characterized in that the parts ( 13 . 14 . 15 ) of the inner ring part ( 10 ) are interconnected by means of a screw connection. Calibration standard according to one of claims 1 to 7, characterized in that the end faces ( 5 . 6 . 11 . 12 ) and the bearing surfaces ( 8th . 9 . 16 . 17 ) are ground. Calibration standard according to one of claims 1 to 8, characterized in that its parts ( 4 . 10 ) made of hardened steel. Calibration standard according to claim 9, characterized in that its parts ( 4 . 10 ) consist of ball bearing steel 100 Cr 6.

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