DE4402401A1 - Circular protractor with multi-position scanning heads - Google Patents

Abstract

The circular protractor (1) for e.g. setting the relative orientation of a workpiece w.r.t. a machine tool is formed from a circular plate (2) inscribed with the calibration seal (3) having a centre (B). A spindle or shaft of the machine tool having an axis (9) carries the plate (2) and due to imperfect alignment of the assembly a resultant eccentricity (e) exists between the centres (0,9). In order to compensate for errors due to this eccentricity four scanning heads generate sinusoidal signals for comparison by a unit (10) in which their respective phase differences enable compensation for the eccentricity (e) and evaluation of an absolute result.

Description

The invention relates to an angle measuring device with several sampling points according to the preamble of claim 1.

Such angle measuring devices are used in particular in processing machines for measuring the Re relative position of a tool with respect to a bear machining workpiece as well as coordinate measurement machines for determining position and / or dimensions test objects.

Both are subsumed under angle measuring devices absolute as well as incremental - i.e. relative - Angle measuring devices in which the division of a Graduation carrier from a scanning unit to the generation periodic sampling signals sampled from which measuring in an evaluation device values for the relative position of the two to each other movable objects, such as the  Tool and the workpiece or both associated machine parts of the processing machine, be won.

In the case of an angle measuring device, the division of the Division carrier but partial division inaccurate have features. In addition, eccentricities can between the angular division and the axis of rotation of the occur both objects to be measured. This featured called disturbances can negative out have effects on the required measuring accuracy. With such position measuring devices can but these negative interferences on the measuring accuracy can be largely avoided, that the division of the division carrier by several Scanning units, for example on two or four Sampled points and those of the samples units generate periodic scanning signals same phase position superimposed on each other analog become. Through this analog overlay the periodic scanning signals can partial Tei inaccuracies are averaged out. With two Scanning units can be with an angle measuring device tion eccentricity error and with two more Scanning units the so-called 2ϕ error of the part disc are eliminated.

US-4,580,047-A describes an angle measurement direction with two scanning units on two diametrical opposite sampling points for elimination of eccentricity errors and for monitoring the Phase position of the periodic scanning signals.  

DE-18 11 961-A also discloses a win kelmeßeinrichtung with two scanning units on two diametrically opposite sampling points whose periodic scanning signals each other in analog form be additively superimposed, so that in addition to the ineffectiveness collection of possible division inaccuracies the indexing disc also the eccentricity error Storage of the index plate can be eliminated.

The z. B. in the double scanning of the angular division an angle measuring device by means of the two Ab Probe units won at the two sampling points nenen two periodic scanning signals of the same Pha In the theoretical case, one location does not have one existing eccentricity no mutual Pha shift on. The practically always there However, eccentricity causes a mutual pha shift of the two periodic samples gnale that to a certain extent without after partial effect on the accuracy of measurement can be sen; the still allowed eccentricity should therefore be a tenth of the lattice constant (Period length) of the angular division must not be exceeded If this limit is exceeded, there is the danger that the analog sum signal of the two periodic scanning signals becomes too small. Amounts the eccentricity a quarter of the lattice constant the angular division, so hurry the first periodic Scanning signal of the first scanning unit on the first Sampling point in phase before 90 and the second Sampling signal of the second scanning unit on the two th sampling point by 90 ° in phase, so that the two periodic scanning signals one against side phase difference by 180 °, the leads to an extinction of their sum signal, so that no measured value can be formed.  

The danger of exceeding this limit exists especially at high accelerations due to shocks or vibrations during machining machine during workpiece processing. In this The case is double scanning, which is in normal operation serves to increase the measuring accuracy, from after partly because the two periodic scanning signals at their total formation mutually or entirely can at least partially cancel, so that errors Adhesive measurement results are the result.

DE-37 26 260-A is an angle measuring device device with several scanning units on several described touch points, where the through a present eccentricity is mutual Phase shifts of the periodic obtained Scan signals are checked. Returns this about checking the mutual phase shifts of the periodic scanning signals of the various Ab scanning units at the associated sampling points inadmissible exceeding of a specified tole ranzbereiches, so the periodic scanning gnale of the different scanning units by means of a control device weighted unevenly; there become the amplitude of a periodic scan signals increased and the amplitude of the other periodic scanning signals reduced so that a partial or even total cancellation of their sum formation of men is avoided. This position measurement direction is because of the control device Weighting of the periodic scanning signals relative elaborately constructed.  

With none of the above incremental - is relatively measuring - angle measuring devices an absolute position determination of the relative to mutually movable elements possible.

The invention has for its object a bottom Sition measuring device of the aforementioned Gat to specify in which from the periodic Ab probe signals of several scanning units on several Sampling points the absolute position of the relative to mutually movable objects to be measured can be telt and the high accuracy points.

This object is achieved by the Merk male of claim 1 solved.

The advantages achieved with the invention exist in that with an angle measuring device a corresponding evaluation of the measured values of the individual scanning units by means of at least one resulting signal the location of the eccentricity and thus the absolute position of the pitch circle can be averaged, with a multiple from palpation with four scanning units of the eccentric errors and the accuracy is increased.

Advances advantageous embodiments of the invention one the subclaims.

Embodiments of the invention are based on the drawing explained in more detail.  

Show it

Fig. 1 shows an angle measuring device with four sensing units and an evaluation device,

Fig. 2 shows the principle of the invention with reference to schematic illustrations 2 a to 2 c, and

Fig. 3 shows a possible variant.

In Fig. 1, an angle measuring device 1 diagrammatically shown schematically, is mounted in a disk 2 with an angular pitch 3 of a shaft 4, which ject with a not shown rotatable Ob, for example, a spindle of a machine table of a processing machine, is connected. Two groups 5 , 7 ; 6 , 8 of scanning units 5 , 7 ; 6 , 8 are connected to a stationary object (not shown), for example the bed of the processing machine, and feel the angular pitch 3 of the indexing disk 2 to generate two periodic scanning signals 5 _s , 5 _c , 7 _s , 7 _c ; 6 _s , 6 _c ; 8 _s , 8 _c when the indexing disk rotates with respect to the four scanning units 5 , 7 ; 6 , 8 from. The two periodic scanning signals 5 _s , 5 _{c from} the first scanning unit 5 and the two periodic scanning signals 7 _s , 7 _c ; 6 _s , 6 _c ; 8 _s , 8 _{c of} the further scanning units 7 ; 6 , 8 each have an opposite phase shift by 90 °, which is used in a known manner to discriminate the direction of rotation of the indexing disk 2 . To further explain the invention, only one of the scanning signals 5 _s , 7 _s ; 6 _s , 8 _{s of} the scanning units 5 , 7 ; 6 , 8 discussed.

The center 0 of the index plate 2 or the win kelteilung 3 may have an eccentricity 3 with respect to the axis of rotation 9 of the shaft 4 . This eccentricity e can be caused by an imperfect centering of the center 0 of the indexing disk 2 or the angular pitch 3 with respect to the axis of rotation 9 of the shaft 4 or by bearing errors of the shaft 4 or by accelerations as a result of shocks or vibrations of the processing machine which the indexing disk 2 is currently out of away from their central position, be effected.

But it can also - and that is for the invention of importance - be specified.

This eccentricity e causes a phase shift 2β which is to be understood in such a way that the two periodic scanning signals 5 _s , 7 _{s of} the first and third scanning units 5 , 7 lead, for example, by the phase shift + β and / or lag and two periodic scanning signals 6 _s , 8 _{s of} the second and fourth scanning units 6 , 8 have no phase shift in relation to the required phase positions 0 °, 90 ° with no eccentricity e.

This can be explained by the fact that an effective Eccentricity e in a coordinate direction in the in addition to the right-angled coordinate direction the Ex centricity is maximally recognizable, however in the Coordinate direction in which the eccentricity acts is sam, but is not recognizable.

In a corresponding manner, the above also applies to the signals of the two diametrical scanning units 6 and 8 .

The position of the eccentricity e to the diametrical scanning units 5 , 7 ; 6 , 8 is therefore a measure of the absolute position of the angular division 3 .

From the mentioned phase shifts of the scanning signals to one another, a resulting signal can be generated in the evaluation unit 10 , which has a largely sinusoidal course. This signal is divided depending on the resolution of the angular division 3 so fine that a clear connection of the incremental signals to that resulting signal is possible.

Based on the schematic representations in Fig. 2 with its Teilfig. 2A to 2E explains how the absolute position is derived from the eccentricity e. In part. 2A is a schematic angle measuring device 1 according to FIG. 1 is provided. The index plate 2 or the angular pitch 3 is mounted eccentrically around a pivot point 9 , so that the center 0 of the angular pitch 3 deviates from the pivot point 9 by an eccentricity e. Of the four scanning units 5 , 7 ; 6 , 8 are scanning signals 5 _s , 5 _c , 7 _s , 7 _c ; 6 _s , 6 _c ; 8 _s , 8 _c generated in the manner described for Fig. 1. To simplify the explanations below, here - as already mentioned - only the relationships between one of the scanning signals 0 ° and 90 ° of the scanning units 5 , 7 ; 6 , 8 received, since the conditions correspond accordingly.

In the partial fig. 2B, 2C, 2D, the graduated disk 2 with the angular graduation 3 is shown rotated by 90 ° relative to the preposition, which shows a position of the angular graduation 3 shifted by the eccentricity e relative to the scanning units 5 , 6 , 7 and 8 .

In linear representation of this is in the Teilfig. 2E shown again for the different scanning units 5 , 6 , 7 , 8 and angular positions up to a full revolution or full period of 360 °.

The linearly plotted angle division shows the position to the respective scanning unit 5 , 6 , 7 , 8 under the influence of the eccentricity e for each rotation angle of 0 °, 90 °, 180 °, 270 °, 360 °, which leads to the phase shift shown in FIG. 1 + β, 0, -β, 0 of the scanning signals 5 _s , 5 _c , 7 _s , 7 _c ; 6 _s , 6 _c ; 8 _s , 8 _c leads.

From this it can be seen that the absolute angular position can be determined at any time when scanning an incremental angle graduation 3 with a plurality of scanning units 5 , 6 , 7 , 8 , since the phase shift between the scanning signals 5 _s , 6 _s , 7 _s , 8 _s or 5 _c , 6 _c ; 7 _c ; 8 _{c is} directly dependent on the eccentricity e.

The embodiment according to FIG. 3 shows that the scanning units ( 53 , 73 ; 63 , 83 ) do not necessarily have to be arranged diametrically in a row, the groups not having to be at right angles to one another. The similar components with the components according to the figure have the same reference numerals as there, but which are supplemented by the figure index. To determine the absolute position of the angular pitch 33 , a computer must be installed in the evaluation unit 103 , which stores the positional relationships of the scanning units 53 , 73 ; 63 , 83 are taken into account in relation to one another and the position value is corrected.

Claims (4)

1. angle measuring device (1) transmits (0) with a rotatable about a pivot point (9) part plate (2), the telpunkt an incremental angular graduation (3) with the with and of several, on at scavenging of the partial disk (2) arranged Abtastein units ( 5 , 7 ; 6 , 8 ) are scanned, which generate mutually phase-shifted scanning signals ( 5 _s , 5 _c , 7 _s , 7 _c ; 6 _s , 6 _c , 8 _s , 8 _c ), the center point ( 0 ) the angular division ( 3 ) and the pivot point ( 9 ) of the indexing plate ( 2 ) are displaced from one another by an eccentricity (e), which causes the angular division ( 3 ) in each angular position to be clearly determined by the eccentricity (e) Absolute position relative to the scanning units ( 5 , 7 ; 6 , 8 ). 2. Angle measuring device according to claim 1, characterized in that the determination of the absolute position of the angular division ( 3 ) relative to the scanning units ( 5 , 7 ; 6 , 8 ) in an evaluation unit ( 10 ) by means of the relative phase shift of the scanning signals ( 5 _s , 6 _s , 7 _s , 8 _s or 5 _c , 6 _c ; 7 _c ; 8 _c ) to each other, from which at least one resulting signal is obtained which represents the position of the eccentricity (e). 3. Angle measuring device according to claim 2, characterized in that the resulting signal is interpolated such that its interpola tion steps of the period of the incremental scanning signals ( 5 _s , 6 _s , 7 _s , 8 _s or 5 _c , 6 _c ; 7 _c ; 8 _c ) correspond and can be connected to them synchronously. 4. Angle measuring device according to claim 1, characterized in that the scanning units ( 5 , 7 ; 6 , 8 ) form two groups ( 5 , 7 ) and ( 6 , 8 ), of which the scanning units of each group pe ( 5 , 7 6 , 8 ) are diametrically opposite and the groups ( 5 , 7 ; 6 , 8 ) form a right angle to each other.