DE3322713A1 - Method and device for continuous measurement of the rolling angle of a movable machine part - Google Patents

Abstract

The invention relates to a method and a device for continuous measurement of the rolling angle of movable machine parts which are moved along a preferably rectilinear line of movement. To be specific, a polarimetric angular measurement is provided for the purpose of determining rolling angle, in which polarised light with a defined direction of polarisation is transmitted in the direction towards the machine part. Arranged on the movable machine part is the analyzer, which co-executes the rolling movements of the machine part. Arranged behind the analyzer is either a light detector or a reflector which retroreflects the analyzed light onto the light source; in the latter case, the light detector is actuated via an inclined semi-reflecting mirror which can form a single unit together with the light source. The direction of polarisation of the transmitted light beam can be varied by a Faraday modulator in order to compensate the rolling angle which occurs. For the rest, the direction of polarisation can be oscillated with high frequency about a central position in order to increase the measurement accuracy, the output signal being evaluated at the light detector with regard to its harmonic components.

Description

Method and device for ongoing measurement

of the roll angle of a moving machine part The invention relates to a method and an apparatus for the ongoing measurement of the roll angle of a movable Machine part according to the preamble of claim 1 or according to that of claim 8, as it is for example from the book publication by M. Weck "machine tools", Volume IV, Metrological Investigation and Assessment Page, 39 appears as known.

In the case of the known roll angle measurement, a defined Distance to each other two laser beams from the light source to the moving machine part sent out and received there by position-sensitive light detectors. Through the To a certain extent, a reference plane is spanned for both laser beams. Through the two position-sensitive light detectors, a movement of the machine part determined transversely to the travel line with respect to the reference plane, whereby not only Rolling movements, i.e. rotary movements to a parallel to the travel line Axis of rotation, but also parallel relocations of the machine part can be determined in the horizontal and vertical directions. The disadvantage of this type of Roll angle measurement is that it is not easily possible to use two light beams to be sent parallel to each other with the required accuracy.

Even very small deviations from the parallelism of the two light rays can mean screwing the reference "plane" and thus not at all simulate the existing rolling movement of the moving machine part. Furthermore the mutual distance between the two light rays must not be too small to a sufficiently high resolution of the two position-sensitive light detectors to get. If the distance between the two light beams is sufficiently large However, these are already so far apart that they are not always the same Temperature conditions for both light rays can be assumed.

Accordingly, the suffer in different temperature stratifications Air the two rays of light have different refractions, so they are due solely to them which no longer run parallel to one another with sufficient precision.

Due to the thermals of the air, the course of the jet is in its position not constant over time, but fluctuates in one that influences the measurement result Extent.

The object of the invention is to provide a roll angle measurement that only needs a single light beam, so that parallelism problems even arise not put and with which also a temperature stratification of the air and accordingly an odd-line beam spread is also irrelevant for the measurement result.

According to the invention, this object is achieved by the characterizing features of claim 1 (method) or by the characterizing features of claim 8 (device) solved. The reference plane for the roll angle measurement is here the polarization direction of the emitted light, which is not influenced by temperature still changed by the earth's magnetic field; at least there are corresponding influences the temperature and the geomagnetism are completely negligible in the present case. The polarimetric Angle measurement method is known per se and, for example, in the book publication "Basics of polarimetry" Berlin 1970 presented in detail by Dr.J.Flügge. It is an examination method for translucent substances, which are penetrated by the polarized light and have a rotating effect exercise the plane of polarization. In the transfer of this angle measurement method, which is known per se the invention is seen on the roll angle measurement.

Appropriate refinements of the invention can be found in the subclaims can be removed. In addition, the invention is based on various in the drawings illustrated embodiments will be explained below; show: figure 1 shows the schematic structure of a roll angle measuring device in a first embodiment, Figure 2 shows another embodiment of an arrangement for roll angle measurement, figure 3 shows the modulation in three different related diagrammatic representations the polarization direction around a central position according to a sine function to increase the resolution accuracy, Figures 4 and 5 representations similar to Figure 3, but with a modulation of the polarization direction according to a triangular function (Fig 4) or according to a rectangular function (Figure 5), Figure 6 is the block diagram for a Evaluation of the output signal of the light detector in a simple design and figure 7 additional parts in a block diagram for evaluating the light detector in a four-quadrant version that is sensitive to the beam position.

A movable machine part is on a bed 1 along a straight line 2 movable along; the roll angle measurement should determine whether and possibly to what extent when moving the machine part along the travel line rolling movements, i.e.

Rotary movements around an axis of rotation that is parallel to the travel line appear. Of course, these angles are very small, and it depends to capture these small angles particularly precisely.

For this purpose there is a riarimeter arrangement on the machine bed 1 or the machine part 2 is provided, which is a stationary at the beginning of the travel distance arranged light source 3 with a polarizer 4 contains. The polarizer 4 light passing through is very precisely linearly polarized with a clearly fixed one Polarization plane. The light beam is at least approximately parallel to the travel line the moving machine part; the parallelism of the light beam in this Regarding this, no great demands are made. It just has to be ensured be that the light beam along the entire travel distance always on the appropriate optical elements on the moving machine part meet in the machine part itself the so-called analyzer 6 is arranged, which is also a polarizer, its However, the direction of polarization is pivoted by 90 "with respect to that of the polarizer 4 is. A light detector 7 is arranged in the beam path behind the analyzer 6, the amount of light passing through the analyzer with great sensitivity can determine. With an exact transverse position of the analyzer 6 in relation to the polarizer no light at all passes through the analyzer, only if there are deviations from this lateral position, which can be traced back to slight rolling movements of the machine part can be, a small portion of light passes through the analyzer 6, the the greater the roll angle, the greater it is. The light detector 7 can - as in Figure 1 is shown in full lines - arranged stationary at the end of the travel path his, which has the advantage that there are no moving lines to this light detector need to be relocated. The other Placement option indicated by dashed lines consists in that the light detector is arranged on the movable machine part is; it can then be combined with the analyzer 6 to form a structural unit. Though a movable line must then be laid to the light detector, but offers the combination with the analyzer 6 provides the possibility of shielding stray light even better than with isolated installation.

To with the polarimeter arrangement shown in Figure 1 for measurement of the roll angle, the analyzer would always have to be able to detect it exactly into the exact transverse position opposite, taking into account the roll angle that occurs the polarizer 4 are pivoted and continuously this pivot position of the analyzer be recorded as a roll angle signal. The pivoting could be mechanized and always set to maximum light attenuation. However, it would then be in In each case a moving line to the one traveling on the moving machine part To lay analyzer 6. In addition, there would be a mechanical pivoting of the analyzer 6 relatively slow and the entire roll angle measurement would be very time-consuming. To the Configure the analyzer 6 as a purely passive element without measuring or control lines to be able to, and to control the beam path to maximum light attenuation without being able to move mechanical parts is behind in the beam path the polarizer 4 fixedly arranged a Faraday modulator, which together with the Light source 3 and the polarizer 4 can be combined into one structural unit. in the Faraday modulator is based on electromagnetic Way a parallel A magnetic field aligned with the direction of the beam is generated, which corresponds to the Faraday effect has a light rotating effect on the polarized light. This light rotating Effect depends not only on the length of the magnetic field, but also on it Strength. The latter can be caused by the level of the excitation current for the electromagnetic generated magnetic field can be influenced.

Thanks to the Faraday modulator, it is possible to do this in an electromagnetic way the polarization direction is pivoted exactly transversely to the forward direction of the analyzer and thereby the direction of polarization to the greatest possible light attenuation Light detector 7 are controlled. The excitation current on the Faraday modulator, the is determined at maximum light attenuation is a measure of the roll angle of the machine part 2.

Because the characteristic curve between transmitted light intensity on the one hand and the pivot position of the analyzer on the other hand not very clearly pronounced Extremum has - it is basically a sine curve - can do the exact one Minimum can only be determined relatively imprecisely. To get an increase in accuracy here to enable it is provided that the polarization direction with a defined frequency and a defined amplitude is oscillated around the respective central position and that the at the light detector 7 pending oscillating output signal with regard to its time successive peak values is evaluated. This oscillation of the The direction of polarization can be carried out by means of the Faraday modulator 5, in that the intensity of the magnetic field fluctuates accordingly. Figure 3 shows in its part a the course of the characteristic curve 10 of the analyzer 6, whereby There the middle extremum in the area of the 90 "point is of particular interest. In part b of FIG. 3 there is an oscillation of the polarization direction in full lines shown symmetrically around the 900 point according to a sine function. In part c of this figure is the resulting output signal at the light detector 7 in its course over time. For each half-wave of the oscillation of the polarization direction in part b of the figure there is a full oscillation at the output signal of the light detector generated. With an exact transverse position opposite the central oscillating polarization direction the direction of transmission of the analyzer is therefore a at the output of the light detector Signal with twice the frequency as the fundamental frequency of the oscillation of the polarization direction queue. With a slightly offset arrangement of the central position of the oscillating polarization direction compared to the 90 "point - shown in dashed lines in FIG. 3b - the harmonic component increases decreases very quickly at twice the frequency. That means the harmonic component with opposite the basic frequency of double frequency has a very narrow one in the area of the 90 "point pronounced maximum, which enables the precise detection of the exact transverse position of the polarization direction of the incident light and the direction of passage of the analyzer 6 are used will. The modulation of the polarization direction does not need to be based on a sine function to be done; a triangle function can also be used for this - as FIG. 4 shows will. There, too, is recognizable. that at one exactly symmetrical to the 90 ° point lying modulation in the temporal depicted in part c of FIG The course of the output signal iD of the light detector 7 has a triangular-like function with twice the frequency - octave signal - is begotten against what with asymmetrical modulation, this octave component decreases very drastically. In figure 5, finally, it is also shown that the direction of polarization also follows a rectangular function can be modulated. With symmetrical modulation around the 90 "point, the output signal is iD on the light detector is consistently high, whereas with asymmetrical modulation clearly changing signals can be detected on the light detector.

It has been shown that it is not only the octave signal that increases the accuracy Signal curve, but that even higher harmonic components in the output signal of the light detector 7 can be used to increase the accuracy. In the block diagram according to FIG. 6, the output of the light detector 7 is several Parallel filter / rectifier 11 connected, the individual filters differ with regard to the level of the transmitted frequency. In general In the case of narrow band filters, the only relatively narrow spectral components of the output signal and determine its peak or mean value the direction of polarization is modulated according to a sine law, only whole numbers occur Multiples of the fundamental frequency as harmonics, so that the filters on the fundamental frequency corresponding bandwidth can be designed with regard to their passage. The parallel filters 11 is followed by arithmetic unit 12 in which the individual filtered signals processed in a certain way can be. For example, it has been shown that the ratio from the Peak value of the fundamental frequency component of the output signal on Light detector 7 to the peak value of the oscillation component of the first harmonic of this output signal with good approximation about four times the deviation of the central position of the modulated Direction of polarization corresponds to the exact transverse position, if according to a sine function is modulated. Such a ratio formation can be used to determine a possible one very precisely Determine the remaining angle. In the same way it is also useful to use the ratio value from the peak value of the oscillation component of the second harmonic of the output signal at the light detector 7 on the one hand and the square root of the third power of the vertex value of the oscillation component of the first harmonic to form the other; this ratio corresponds to a good approximation to 0.942 times the above-mentioned angular deviation, where the factor 0.942 is calculated from the square root of eight ninths. if If both options are used, a mean value can be calculated that secures the measurement result, whereby it is based on several different individual measurements leans.

Instead of arranging the light detector 7 in the beam path behind the analyzer 6, this can also be fixed in the area of the start of the travel path of the moving machine part, and thus together with the light source, the polarizer and the Faraday modulator can be combined into one structural unit.

For this purpose must be in the beam path between the polarizer 4 and a partially transparent inclined mirror 9 is arranged in a stationary manner on the analyzer 6, that in the illustrated embodiment by two prisms placed next to one another is formed. Behind the analyzer 6 is a parallel to the light beam arranged reflecting reflector, which is designed as a triple reflector. He must be designed in such a way that it does not change the direction of polarization due to the deflection changes. This triple reflector can advantageously be placed on the movable one Machine part 2 can be arranged and structurally combined with the analyzer 6. One Another possibility, which is indicated by dashed lines in Figure 2, is the list in the area of the end of the travel path. The light detector 7 is at the height of the partially transparent inclined mirror 9 arranged and aligned transversely to the main beam. When arranging a Faraday modulator 5 in the beam path, it is important that the partially transparent mirror lies behind this modulator in the beam path.

Although the useful signal is weakened by the partially transparent mirror, however, this can easily be done by increasing the intensity accordingly the light source 3 are compensated. Advantageous in the embodiment according to FIG 2 is that all parts to be provided with cables are combined in one structural unit can be and accordingly on the movable machine part 2 only passive elements are arranged. Another advantage is that through the two passages of the beam through the analyzer 6, any amount of false light is reduced even more than with just a single entry.

In an embodiment of the invention - be it in the one outlined in FIG or be it in the embodiment sketched in FIG. 2 - the light detector can 7 also be designed to be sensitive to the beam position, so that it does not only determines the intensity of the light passing through the analyzer 6, but also can measure the beam position according to elevation and latitude. Such a position-sensitive light detector 7 'is shown in FIG. 7 in the form of a four-quadrant light detector shown. Due to the division of the photosensitive surface into four independent Areas arranged in the form of an edge can be within the limits of the diameter of the light beam determine how far the light beam is from the center of the light detector in the horizontal direction or eccentrically in the vertical direction. pre-condition this is, however, that the analyzer 6 only eien a limited degree of polarization, for example 50, and that accordingly also with an exact transverse position of the polarization direction of the incident light in the direction of transmission of the analyzer is still noticeable Part of the light falls on the light detector, so that the position of the light beam is determined can be.

Each of the individual quadrants I to IV of the light detector 7 'is provided with a separate exit. In a first adder 13 are for Formation of the total intensity iD of the incident light beam the values at the Outputs of all four quadrants summed up.

In one independent signal processing channel, two other adders 14 'the signals of the two upper quadrants I and II and the Signals of the two lower quadrants III and IV are each added separately and these two signals formed in this way in a further subtraction unit 14 from one another deducted. By comparing this intensity difference (16) with the total intensity of the light beam can be the deviation of the light beam in the vertical position from the Central position, so the dimension 4 z can be determined. In a similar way way is with the two left and with the two right quadrants or their output signals move in the adding units 15 'or the subtracting unit 15 and thus the measure obtained for the horizontal deviation n y.

By designing the light detector in this way and through the position signals that can be achieved in this way can improve the roll angle measurement to that effect that statements about the current position of the roll center can also be obtained can. However, the current position of the roll center can only then be determined exactly if, in addition to the roll angle measurement, there is also the proportion of the parallel displacement of the moving machine part isolated in the horizontal direction and in the vertical direction will.

Another possibility: the current roll center according to the situation to determine exactly, is that at a defined distance parallel to each other two roll angle measuring devices are provided for the same machine part 2, wherein the light detector 7 'is designed to be sensitive to the beam position. The advantage in This double arrangement consists in the fact that also still clear statements about the proportion of a parallel displacement of the moving machine part in horizontal and can be obtained in the vertical direction, i.e. separate measurements in this direction Respect are no longer necessary.

Finally, for the sake of completeness, it should be noted that that the roll angle measurement is not only for straight lines on a bed guide or the like moving machine parts is suitable, but that also the roll angle of such Machine parts can be measured that are not parallel to a bed guide yourself are moved, but the straight lines freely in space be moved, but perform any pivoting movements due to the system. This is primarily intended for roll angle measurements on robot heads, in particular of measuring robots that move along a reference ruler with a feeler finger and drive along a straight line with the tip of the probe, but in larger swivel movements and also lifting movements transverse to the direction of movement carry out. With such a roll angle measurement, a measuring robot can check for measuring accuracy to be checked.

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Claims (14)

A method for the ongoing measurement of the roll angle of a A machine part moving along a travel line with polarized light is sent parallel to the travel line to the machine part and through to the machine part firmly attached to the rolling movement and acted upon by the emitted light optical elements obtained information corresponding to the angle of the rolling movement is characterized by the use of the polarimetric angle measurement method with a stationary polarizer (4) at the beginning of the travel line, with on the machine part (2) attached analyzer (6) as an optical element and with it arranged behind it Light detector (7). 2. The method according to claim 1, characterized in that the polarization direction of the light behind the polarizer (4) is always pivoted so that the Light detector (7) falling intensity is minimal and that the pivot position of the in the direction of polarization of the panned light is used as a measure of the roll angle will, 3. The method according to claim 1 or 2, characterized in that that the polarization direction with a defined frequency and a defined amplitude is oscillated around the respective central position and that the pending on the light detector (7) oscillating output signal with regard to its temporally successive peak values is evaluated. 4. The method according to claim 3, characterized in that the oscillating according to a sine (Figure 3), according to a triangle (Figure 4), sawtooth or square function (Figure 5) takes place. 5. The method according to claim 3 or 4, characterized in that from the electrical output signal of the light detector (7) filtered out the harmonic components and ratio values of the peak values of various harmonic components are continuously formed and their temporal course can be observed. 6. The method according to claim 5, characterized in that at one Oscillation of the direction of polarization according to a sine function of the peak value the ratio of the fundamental frequency component of the output signal at the light detector (7) is set to the square root of the peak value of the vibration component of the first Harmonic. 7. The method according to claim 5, d a du r c h g e k e n n z e i c h n e t that with an oscillation of the polarization direction according to a sine function the peak value of the oscillation component of the second harmonic of the output signal at the light detector (7) is set in relation to the square root of the third power the peak value of the oscillation component of the first harmonic. 8. Device for ongoing measurement of the roll angle along one a moving line of moving machine parts, with a polarized light parallel to the travel line emitting light source on the machine part and with a firmly attached to the machine part, participating in the rolling movement and sent by the Light acted upon optical element which - at least indirectly - one of the Provides information corresponding to the angle of the rolling movement, characterized by a polarimeter arrangement for roll angle measurement; with one at the beginning of the travel line Stationary polarizer (4), with one attached to the machine part (2) Analyzer (6) as an optical element and arranged behind it in the beam path Light detector (7). 9. Apparatus according to claim 8, characterized in that the light detector (7) stationary at the end of the travel line opposite the light source (3) is arranged. 10. Apparatus according to claim 8, characterized in that the light detector (7) is arranged on the movable machine part (2). 11. The device according to claim 8, characterized in that in the beam path between the polarizer (4) and the analyzer (6) is a partially transparent inclined one Mirror (9) is arranged that - seen from the light source (3) - behind the Analyzer (6) a reflector (8) which reflects the light beam in parallel is arranged and that the light detector (7) is stationary in the area of the partially transparent mirror (9) arranged to the side of the beam path between polarizer (4) and analyzer (6) is. 12. Device according to one of claims 8 to 11, characterized in that that in the beam path between polarizer (4) and analyzer (6) a Faraday modulator (5) is arranged. 13. Device according to one of claims 8 to 12, characterized in that that the light detector (7) is designed to be sensitive to the beam position and apart from the light intensity of the total beam also measures its beam position according to altitude and latitude that the analyzer (6) has only a limited degree of polarization. 14. Device according to one of claims 8 to 12, characterized in that that two roll angle measuring devices parallel to each other at a defined distance are provided for the same machine part (2).