DD297701B5 - METHOD OF MEASURING LENGTH - Google Patents

Abstract

The invention concerns a method of measuring lengths, in which a scanning device scans a substrate (1) with a graduated scale (2), having a graduation band, and reference marks (7) various distances apart along at least one other band (3). The signals from the scanning device are processed in a processing unit and in a display unit, the various distances between the reference marks (7) being determined in graduation-band units by scanning the graduated scale (2). From these interval-measurement signals, information is obtained in coded form on the absolute position value of the reference marks (7). At a transmission position (Pn2) on the graduation band which is displaced a whole number of graduation units (zo), where z is >/= 1, in the direction of travel from a position (Pn1) being determined, a value is fed by the processing device to the display unit as the current position of the measurement device, this value containing the absolute value of the position being determined and the shift (zo), the shift (zo) of the transmission position (Pn2) being determined from the graduation signals in the graduation band, for supplying the absolute value decoded in the processing device, with respect to the last code pulse.

Description

For this 1 page drawings

Field of application of the invention

The method is applicable to translational measuring systems, in particular high-resolution measuring systems for long lengths of machine tools and length and coordinate measuring machines.

Characteristic of the known state of the art

In machine tool and general engineering length measuring systems are used on a large scale. In principle, two types are known, one type being described by the term absolute value system and the other type by the term incremental counting system. Absolute value systems, e.g. CH 374207, and incremental systems, e.g. CH 499091, each have a number of specific advantages and disadvantages. A number of solutions combine the advantages of both with specific hybrid solutions and avoid their disadvantages, e.g. DT 2416212 B2 or DE 3144334 C2. In the length and angle measuring device according to DE 2416212 B2, a graduation carrier is used with a second reference track parallel to the incremental scale and identical reference marks. The reference marks can also be composed of individual stamps. The absolute value of each reference mark is determined from the respective specific distance to exactly one adjacent reference mark, these different distances between the adjacent reference marks being determined by the scanning of the increment track. To identify the individual identical reference marks, these and an adjacent reference mark must be scanned and their mutual specific spacing in increments of the incremental track determined and evaluated together with the measuring direction information. At reasonable maximum distances of the reference marks, the information content of a so-coded reference track is limited. It follows that this coding is not suitable for arbitrarily long measuring systems.

In DE 3617254A1 a measuring method is realized in which at least two distances between this reference mark and two further reference marks are determined for determining the absolute value of a reference mark. This solution has the advantage that a much higher information content can be coded in reasonably small intervals over the reference marks. However, the unambiguous decoding of the different distances is more complicated and the occurring time delay between the computationally determining the two distances to this reference mark and the assignment of the absolute position to this same reference mark is greater and can limit the permissible travel speed. DE 3324004 A1 describes a measuring method in which, analogously to DT 2416212 A1, the determination of the absolute value of a reference mark takes place by means of the decoding of the respective specific distance to an adjacent reference mark. To increase the Codierumfanges here a second parallel reference mark track is additionally introduced, which must be scanned and evaluated in parallel

 All listed measuring methods have the following defects:

The determination of the absolute value of the respective reference mark would have to take place simultaneously with the scanning of the reference mark by the scanning unit when driving over. However, a finite time is necessary for the decoding of the distances and the provision of the stored absolute values in the Aliswerteeinrichtung, in particular if microcomputers are to be used for the decoding. At high travel speeds, the provided absolute position would no longer be identical to the actual position.

For applications in which the absolute positions, which are considered as a metrological grid, with variable error components, such. B. temperaure error or load-dependent deformation shares are to be corrected by micro-computers, is not sufficient time for this correction calculation available.

Object of the invention

The aim of the invention is to extend the usefulness of a length measuring system containing a microcomputer by increasing the Meßsignalverarbeitungsgeschwiri ligkeit.

Explanation of the essence of the invention

The invention has for its object to provide a measuring method for a quasi-absolute incremental length measuring system in which a graduation carrier is scanned with distance-coded reference marks a reference track, and sufficient time between the recognition of the distance codes of the reference marks and providing the absolute position to decoding and guaranteed for correction.

The object is achieved in that in a method for measuring lengths, in which a graduation carrier having a grid pitch with a count track and reference marks at different distances in at least one other track is scanned by a scanning direction, wherein the scanning signals in one Evaluation device and a display device are further processed, and in which the different distances of the reference marks to each other by scanning the grid division in counting units of the count track are determined, being obtained from these distance signals information in coded form on the absolute values of the position of the reference marks, the code for the absolute value a reference mark is formed by scanning two further reference marks, which lie in the direction of travel before this reference mark.

The offset by the counting amount Z ₀ can be selectable in the evaluation device. The transfer value from the evaluation device to the display device may include an additional correction value.

The offset Z ₀ can on the one hand at a known maximum scanning speed and the maximum time required for the decoding of the code, for auxiliary operations such. B. current temperature corrections of the position P _n ι and for the absolute value provision in the evaluation are set as a constant. It results from the product of maximum scanning speed and the time required for the absolute value provision. On the other hand, the arrangement itself may contain electronic means which, after completion of decoding, auxiliary operations and absolute value provision, determine the current z ".

Depending on the direction of travel, the z _{o is to be} regarded as a positive or negative count.

According to the quasi-absolute incremental length measuring method according to the invention, the time is available for decoding, auxiliary operations and absolute value provisioning which requires the relative displacement of the scanner from the moment of sampling of the last reference mark belonging to the encoded code from the Z ₀ increments of the counter track becomes.

Depending on the hardware and / or software solution for the evaluation device, the counting amount for a given maximum relative movement between division carrier and scanning device can be selected so that a sufficient time for the decoding, auxiliary and absolute value provision is available.

The method makes it possible that in the quasi-absolute incremental length measuring the absolute values associated with the positions P _{n of} the count track are provided without time delay and thus the absolute positions provided are identical to the actual positions even at high speeds. Furthermore, the absolute positions current error components can be assigned without affecting the dynamic behavior of the measuring system.

Due to the time span between the code recognition and the provision of the absolute values created according to the invention, economically advantageous microcomputer solutions can be used, above all, also for the decoding of double codes and for additional correction calculations.

embodiment

The invention will be explained in more detail below using an exemplary embodiment. In the drawing show

Fig. 1: a graduation carrier with a single-coded reference track, and Fig. 2: the arrangement of the scanning elements in a scanning device.

The quasi-absolute incremental length measuring system, of which only one graduation carrier 1 is shown in the drawing, further comprises a grid division 2 and a scanning device scanning a reference mark track 3, which is connected to an evaluation device which generates electrical evaluation signals. The scanning 4 of the scanning device shown in Fig. 2 comprises a Marku b for scanning the reference mark track 3 and a counter-grid 6 with four 90 ° out of phase areas for scanning the grid division. 2

FIG. 1 shows a simply coded reference mark track 3. The information about the position P _{n 1} is in the case of the forward movement in the division direction 8 in the code marks C _n and C _n _ ι or in their distance d _n included, which is determined based on the grid division 2 by means of their derived count signals.

The following parameters should be specified for the selected example:

- Increment of the counting track: 1 pm

- Maximum relative speed (scanning speed) between grid division and scanning device: 1 m / s

- Maximum time for decoding, for auxiliary operations, such. B. current temperature corrections ^Pos: tions P _n and the absolute value of deployment in the evaluation: 0.5 ms

Ai.s the product of maximum scanning speed and the time required for the absolute value provision is oin counting amount z ₀ to 500pm.

This offset of z _o = 500 pm - corresponding to 500 counting units of the counting track - is set as a constant in the evaluation device.

Upon reaching position + P., 2. which differs by Z ₀ from P _n , is from the evaluation a transfer value to the

Display device as the current position of the measuring device passed, which the absolute value of P _n ,, the offset of

+ 500pm and possibly an additional correction value.

The offset z _{0 of} the position + P "2 for the transfer of the decoded in the evaluation and possibly corrected absolute value Pni against the code pulse C _n is determined based on the count signals in the counting track from P _n .

In the case of the backward movement, the information for the position P _n , in the code marks C _n +, and C _n or in their

Distance d _n ,., Included.

It is advantageous that z. B. in a forward movement after passing the scanner on C _n -, and C "the

Distance information can be decoded, and that for this decoding and the absolute value provision of P _n , and possibly

time is available for further correction calculations in a processor and the calculated and corrected absolute value is available for + P "2 before this position is reached, and that upon reaching this position, the absolute value is immediately available to the display device.

Claims (3)

1. A method for measuring lengths, wherein a graduation carrier having a grid pitch with a count track and reference marks at different distances in at least one other track is scanned by a scan direction, wherein the scan signals are further processed in an evaluation and a display device, and in which the different distances of the reference marks to each other duich scanning of the grid division in counting units of the counting track are determined, being obtained from these distance signals information in coded form on the absolute values of the position of the reference marks, characterized in that at a position P _{n2 of} the counting track, the is offset by an integer count z ₀ >: 1 in the direction of travel relative to a position P _n1 , the evaluation device transmits a transfer value to the display device as the current position of the measuring arrangement, which Jen / absolute value of P _n1 and the Ve ₀ and that the offset z _{o of} the position P _n2 for transferring the absolute value decoded in the evaluation device with respect to the last code pulse is determined on the basis of the count signals in the counting track. 2. The method according to claim 1, characterized in that the offset z _o in the evaluation device is selectable. 3. The method of claim 1 or claim 1 and 2, characterized in that the transfer value from the evaluation device to the display device includes an additional correction value.