DE19815098B4 - Method for measuring turntable deviations - Google Patents

Abstract

Method for measuring turntable deviations with the following steps:
- The center of a test piece (2), which is successively arranged in succession in three spatially different tensions on a turntable (1) is measured by probing by means of a coordinate,
- wherein the test body (2) in a first measuring position (I) outside a center (6) of the turntable (1) and in the vicinity of a turntable surface (3) is arranged,
- The test specimen (2) is arranged in a second measuring position (II) at least approximately in the middle (6) of the Drehti cal (1) and in the vicinity of the turntable surface (3),
And in a third measuring position (III), the test body (2) is arranged at least approximately in the middle (6) of the turntable (1) and at a distance from the turntable surface (3),
- And from the three series of measurements of the three measuring positions (I, II, III), the deviation lines of the turntable are determined, wherein for each series of measurements, the center of the test specimen in each case for different angular positions ...

Description

The The invention relates to a method for measuring turntable deviations.

According to the state In the art turntables are used on coordinate measuring machines. For one Use of rotary tables on coordinate measuring it is necessary that the from Rotary table output angle values and the deviations of the axis of the turntable of an ideal axis of rotation are as low as possible and the uncertainty the coordinate measuring machine is not enlarge.

• 1. Winkelpositionsabweichungen,
• 2. Laufabweichungen der Drehachse, a) axiale Abweichungen, b) radiale Abweichungen, c) Taumelabweichungen.

The deviations of a turntable can be divided into the following components:

• 1. angular position deviations,
• 2. Running deviations of the axis of rotation, a) axial deviations, b) radial deviations, c) wobble deviations.

According to the prior art ( DE 36 37 410 C2 ) discloses a method of measuring turntable deviations using a test specimen having at least three balls which is measured in a plurality of positions on the table.

This prior art methods has the disadvantage that a special test piece with a bracket needed becomes. The specimen must on the one hand have a minimum accuracy. On the other hand, it is expensive this test piece for transport each customer. The prior art method has the further disadvantage that a Variety of measurements in different measuring positions is necessary, which is a certain changeover time requires. Beyond that by the multiplicity of measurements is beyond the measuring time is very high Long. About that In addition, a complicated evaluation by statistics is about all Measurements required.

To the State of the art ("accuracy specifications on turntables and special features of their use on coordinate measuring machines ", VDI reports 529, VDI-Verlag GmbH, Düsseldorf, 1984) belongs Procedure, according to the running deviations the axes of rotation, namely Axial and Radial Ruhe and wobble deviations are known. These Measurements are made according to this Prior art with a one-dimensional measuring system, such as an inductive probe carried out. This belongs to the prior art Method has the disadvantage that as a test specimen a highly accurate ball is required.

Furthermore, according to the prior art ( DE 36 37 410 C2 ) a measurement of the wobble deviation is known to be used in the axially offset displacement transducer in differential circuit. Also in this belonging to the prior art method has the disadvantage that a high-precision test specimen is required.

The The technical problem underlying the invention is that to provide a method of measuring turntable deviations, in which on the one hand a simple test piece is sufficient, at the above In addition, only a few measurements needed be with a simple conversion and a short set-up time, which about it In addition, a short measurement duration has, and in which only a simple evaluation is required.

This Technical problem is solved by the features of claim 1.

Thereby, the existence Test specimen, for example a Ball, in three measuring positions is measured are only three series of measurements required. For the single measurements is just a very simple conversion with a short set-up time required. About that In addition, the evaluation is easy. Another advantage of the method according to the invention is that only low cost for the test piece, the Mount and so on.

According to the inventive method is for example, the ball first eccentrically to the edge of the turntable as far as possible close to the table surface. The ball, for example, simply by means of the usual attached to her stem in the threaded holes Tabletop be screwed.

In This position is the error, the angle of the adjustment Turntable is established, certainly. That is, the correction for scaling of the protractor is made.

in the next Step the ball in the middle of the table directly above the Table top arranged. This can translational errors be determined. about the high altitude hike the error of the Z-degree of freedom is determined.

In the third measuring position, namely in the middle of the turntable, but at a distance from the turntable, the remaining errors are determined, namely the tumbling movements. Because the ball in the measuring positions II and III hardly moves in the measurement of the associated measuring lines in the measuring volume of the coordinate, it has the advantage that geometry errors of the coordinate in the measuring lines II and III are not received, but only in the measuring line I are of importance.

The different measuring positions as well as the corresponding ones test series can also in changed Order to be recorded.

Advantageous is the test specimen as Ball formed. But it is also possible to test specimens of other geometries use.

The inventive method can be done by the software so that the ball quality is not enters, namely by turning the ball pattern.

Further Details of the invention can be found in the dependent claims.

On The drawing is an embodiment of the invention, and show:

1 a first measuring position;

2 a second measuring position;

3 a third measuring position;

4 the determination of the reference circle;

5 the determination of the tumbling error.

1 shows a turntable ( 1 ), which is rotatably mounted in the direction of the arrow (A). On the turntable ( 1 ) is a test specimen ( 2 ) in the form of a sphere near a surface ( 3 ) of the turntable ( 1 ) arranged in a measuring position (I). The ball ( 2 ) is in the edge region of the turntable ( 1 ) arranged. The ball ( 2 ) will now be displayed, for example, in 36 positions of the turntable ( 1 ) is measured by the coordinate measuring machine (not shown). This corresponds to 10 ° steps.

In a first position ( 4 ) (Zero position), the ball ( 2 ). Each ball measurement must consist of at least four touches of the ball surface in order to obtain a center point evaluation of the current ball position. Advantageously, each ball measurement consists of nine to fifteen points.

After this measurement the sphere ( 2 ) into a second position ( 5 ) (shown in dashed lines) by turning the turntable ( 1 ) moves in the direction of the arrow (A), and the ball ( 2 ) is measured again. This will be done in other positions ( 5 ' . 5 '' ) until the ball ( 2 ) again in the zero position ( 4 ) is located.

According to 2 will the ball ( 2 ) in the middle ( 6 ) of the turntable ( 1 ) in the measuring position (II), directly above the table surface ( 3 ). Again, the ball ( 2 ) again, for example in the 36 positions of the turntable ( 1 ), each ball measurement in turn consists of at least four points, whereby the position of the ball center of the ball ( 2 ) is detected.

According to 3 is the ball ( 2 ) again in the middle ( 6 ) of the turntable. The ball ( 2 ) is now but with a greater distance over an extension ( 7 ) to the surface ( 3 ) of the turntable ( 1 ) in the measuring position (III). The extension ( 7 ) may be a commercial extension, which in the middle ( 6 ) of the turntable ( 1 ) is screwed. This requires a set-up time of less than two minutes.

In this position, the ball ( 2 ) again in, for example, 36 positions of the turntable ( 1 ) and the position of the ball center of the ball ( 2 ) detected.

From the three series of measurements of the measurement positions (I, II, III), the six angle-dependent deviation lines of the turntable ( 1 ) (see VDI 2617, part 4).

According to 4 is determined with the help of the results from the first series of measurements (series of measurements according to 1 ) a fitted circle ( 8th ), hereinafter referred to as the reference circle ( 8th ), the surface normal together with the center of an axis ( 9 ) Are defined. On the axis ( 9 ) all the following measurements relate. It is referred to below as the reference axis ( 9 ) designated.

The sphere center of the sphere ( 2 ) was set for the zero position ( 4 ) for one point ( 10 ) in the coordinate system. For the position ( 5 ) the ball center of the ball ( 2 ) to a position ( 11 ) of the coordinate system. The point ( 11 ) is not on the reference circle ( 8th ), so that a deviation of the actual position ( 11 ) from a desired position ( 12 ) is present. Also in the other positions ( 5 ' . 5 '' ) there is a deviation of the actual position from the desired position. For the position ( 4 ), set and actual position ( 10 ) match.

A measuring point ( 14 ), which has a measured center of the sphere ( 2 ) shows that not only a radial deviation from the reference circle ( 8th ), but also an angular deviation dφ. The measuring point ( 14 ) has an actual position ( 15 ) with the coordinates (x _I , y _I , z _I ) with a deviation (dx, dy, dz) from a desired position ( 16 ) with the coordinates (x _S , y _S , z _S ).

The angular position-dependent radial Po deviations of the table center ( 6 ) are calculated from the radial deviations of the center positions of the second series of measurements according to 2 to the reference axis.

The axial deviations (rash) are from the axial (in the direction of the reference axis) deviations of the center positions determined to the reference circle.

According to 5 are the angular position-dependent wobble deviations of the table ( 1 ) from the differences of the radial center deviations of the second and third series of measurements ( 2 and 3 ) to the reference axis ( 9 ) is determined by the height difference lever (h).

The wobble angle δ is determined from the deviation (b) of the ball center of the ball ( 2 ) in position (II) according to 2 and the deviation (a) of the ball center of the ball ( 2 ) in position (III) according to 3 and from the lever (h) according to the following formula:

mit

a ⇀

= Vektor zum Soll-Punkt,

b ⇀

= Vektor zum Ist-Punkt.

The angular position deviations of the turntable ( 1 ) are calculated from the midpoint positions of the first series of measurements ( 1 ) to the respective position on the reference circle, taking into account the angular position-dependent radial position deviations of the table center point in the x and y directions ( 1 ).

With

a ⇀

= Vector to the target point,

b ⇀

= Vector to the actual point.

The deviation of the center of the sphere is determined as follows: X = X I - X S (3) y = y I - y S (3) Z = Z I - Z S (3)

Because the ball ( 2 ) of the second and third series of measurements ( 2 and 3 ) in the middle ( 6 ) of the turntable ( 1 ) is close to the axis of rotation and during the example 36 measuring positions barely moved in the measuring volume of the coordinate (not shown), the geometrical errors of the Koordinatenmeßmaschine do not go here.

From the second and third measurements ( 2 and 3 ) already five of the six deviation lines of the table are calculated.

Only when recording the first measuring line ( 1 ) the ball ( 2 ) is moved through the measurement volume, so that local deviations in the accuracy of the coordinate measuring machine affect the result. Through several measurements of the first series of measurements ( 1 ) in different angular positions ( 4 . 5 . 5 ' . 5 '' ) the ball ( 2 ) off-center on the tabletop and averaging over the measurements can improve the results. Here there is a dependency on the geometrical errors of the coordinate measuring machine.

Likewise, the results of the second and third measurements ( 2 and 3 ) stabilize when recorded and averaged several times. However, the slightly improved stability of the results is not necessarily of such great advantage, considering the increased measurement time. Normally one circulation per line is sufficient.

The thus obtained six error components of the rotary table at the measured angular positions ( 4 . 5 . 5 ' . 5 '' ) are long periodic errors. Values for intermediate positions can be obtained by interpolation.

The total duration of a single measurement (one revolution per measuring line) with conversion to the three ball positions takes about 45 minutes. Outliers when measuring the ball ( 2 ), for example due to dirt on the surface of the sphere, can be detected by examining the spherical shape. According to the invention, the influences of the spherical shape itself can be achieved by rotating the probing pattern on the sphere ( 2 ) can be reduced by means of appropriate software. This is always touched in the same places on the surface of the sphere. So it could also be used balls of poorer quality.

The correction is independent of the position of the turntable ( 1 ) in the measuring volume of the coordinate measuring machine. The method is very easy to perform, for example, on rotary tables with a horizontal axis, since the balls must be screwed only in the table top. There is no special bracket required.

1

turntable

2

Bullet

3

surface

4

Null position

5, 5 ', 5' '

positions

6

Focus

7

renewal

8th

reference circle

9

reference axis

10

measuring point

11

Actual position (Measuring point)

12

Nominal position

14

measuring point

15

Actual position

16

Nominal position

A

arrow

dφ

angular deviation

d, dx, dy

deviation

H

lever

δ

swash angle

a, b

deviations

I, II, III

measuring positions

a ⇀

vector to the target point

b ⇀

vector to the actual point

Claims (11)

Method for measuring turntable deviations comprising the following steps: - the center of a test specimen ( 2 ), which in succession in three locally different fixtures on a turntable ( 1 ) is measured by probing by means of a coordinate measuring machine, - the test specimen ( 2 ) in a first measuring position (I) outside a center ( 6 ) of the turntable ( 1 ) and near a turntable surface ( 3 ), - the specimen ( 2 ) is in a second measuring position (II) at least approximately in the middle ( 6 ) of the Drehti sches ( 1 ) and near the turntable surface ( 3 ), and in a third measuring position (III) the test body ( 2 ) at least approximately in the middle ( 6 ) of the turntable ( 1 ) and at a distance from the turntable surface ( 3 ), and from the three series of measurements of the three measuring positions (I, II, III), the deviation lines of the turntable are determined, wherein for each series of measurements, the center of the specimen is determined for different angular positions of the turntable, and wherein the co-rotation of the probing pattern of Test specimen is made by software. Method according to Claim 1, characterized in that the arrangement and subsequent measurement of the test specimen ( 2 ) takes place in the three measuring positions (I, II, III) in a changed order. Method according to one of the preceding claims, characterized in that the test body ( 2 ) is formed as a ball. Method according to claim 3, characterized that one Sphere measurement from measurements of at least four points on one spherical surface consists. Method according to Claim 1, characterized in that, with the aid of the results from the series of measurements of the first measuring position (I), with the test body arrangement, the eccentric table (8) is arranged eccentrically. 1 ) a fitted circle (reference circle) ( 8th ) whose surface normal together with the center point has an axis (reference axis) ( 9 ) Are defined. Method according to Claim 1, characterized in that the angular position-dependent radial position deviations of the rotary table center point ( 6 ) are determined from the radial deviations of the midpoint positions of the series of measurements of the second measuring position (II) with the test body arrangement in the middle and in the vicinity of the surface of the turntable. Method according to Claim 1, characterized in that the axial deviations (radial deviation) are determined from the axial deviations of the center point positions of the test body ( 2 ) to the reference circle ( 8th ). Method according to Claim 1, characterized in that the angular position-dependent wobble deviations of the turntable ( 1 ) from the differences of the radial center deviations from the series of measurements of the second measuring position (II) with the test body arrangement in the middle ( 6 ) of the turntable ( 1 ) and near the surface ( 3 ) and from the series of measurements of the third measuring position (III) with the test piece arrangement in the middle ( 6 ) of the turntable ( 1 ) and from the surface ( 3 ) spaced from the reference axis ( 9 ). Method according to claim 1, characterized in that the angular position deviations of the turntable ( 1 ) from the center point positions of the series of measurements of the first measuring position (I) with the test body arrangement off-center of the rotary table ( 1 ) to the respective position on the reference circle ( 8th ). Method according to Claim 1 or 2, characterized in that an interpolation of values between the recorded positions of the turntable ( 1 ) is carried out. Method according to claim 1 or 2, characterized in that a shape monitoring of the test body ( 2 ) is performed for the detection of Meßausreißern.