DE1272006B - Device for numerical display of measured values on a non-numbered measuring graduation - Google Patents

Description

Device for the numerical display of measured values on a non-numbered one Graduation addition to registration: L 33298 IX b / 42 d -Auslegeschrift 1187 383 and for additional registration: L 34070 IX b / 42 d Auslegeschrift 1266 519 The invention relates to a device for the numerical display of measured values on a non-numbered measuring graduation, for controlling a counter that counts the units of the scale motor driven by the two-phase principle is provided, and what means for fine adjustment, which control a correction device, according to patent application L 33298 IXb / 42d (German Auslegeschrift 1187 383) and patent application L 3407 () IX b / 42 d (German publication 1266 519).

In the devices described in the aforementioned patent applications the means for fine-tuning are based within a scale interval, which simultaneously control a correction device based on the principle of zero adjustment. The adjustment means can either be operated manually or in the usual way be regulated automatically (line capture). Disadvantageous when using this measuring principle it is that when the scale is moved, its position is not read immediately and continuously can be.

The invention described below with the aid of a few examples is therefore based on the task of eliminating this disadvantage. The invention is characterized in that a scanning device is provided as the means for fine measurement is connected phase-locked to a display device carrying a sequence of numbers is, and that the pulses supplied by the scanning device at least one stroboscopic lamp control in such a way that the flash lamp lights up exactly when the intermediate value Representative number of the sequence of numbers reached a certain position in front of the strobe lamp Has.

The graduation is continuously indicated by a line of light in accordance with Art a tilting oscillation scanned, the tilting amplitude being equal to a scale interval or an even multiple thereof. The display device consists of an interpolation scale that moves in a phase-locked manner and synchronously with the query line will. This scale is in the area of a fixed reading pointer of a Flash lamp illuminated at the moment in which the query stroke a Scale line passed over. Preferably a rotating, is used with a disk arranged in a spiral shape around the axis of rotation and for the display device a circular one running synchronously and phase-locked to it Scale ladder.

On this scale, the start and end values coincide. From this it follows there is an ambiguity in the ad even if one has that in the main application Correction devices described for the coarse counter analogously to the after the stroboscopic method. This ambiguity is eliminated in a further embodiment of the invention that the scale at least exist twice near the initial value 00, which is equal to the final value 1.00 is, and that switching means are provided for switching off one of the two scales, which are coupled to the correction device for the coarse counter.

According to the main application, the coarse counter can be powered by a two-phase stepper motor are driven, the position of which is assigned to the position of the counter that when the correction is switched off, two digits are equally visible on the unit roll are when the position of the stepper motor is the last and first quarter of two corresponds to successive units of scale. The correction sign becomes in further development of the subject after the main application by one through the Indicator disc operated switch given. This switch is useful as photoelectric or magnetically controlled switch.

The two phases for driving the stepping motor can according to the arrangements after the main registration by a mounted on the rule Light-dark rasters can be generated. In a further refinement, they can also go through phase-sensitive rectifiers, synchronous switches or logically equivalent electrical, photoelectric, magnetic or mechanical devices from the phase position between the stroboscopic pulses and the query phases of the precision measuring device are derived, provided that the sampling frequency is sufficiently high relative to the scale movement is chosen.

In a further embodiment, the invention can also be applied to a scale use whose line spacing is a multiple of the digits of the coarse counter is the unit of length represented.

It should also be mentioned that the scanning devices to complete can be connected to a device known per se for zero setting, which consists, for example, of a pivotable plane-parallel plate. The panning this plate can be carried out electrically by means of a synchronous transmitter and receiver and controlled from the display location. In this case there is a on the counter mechanical zero adjuster to be provided.

In the drawings, the invention is shown in some exemplary embodiments. It shows F i g. 1 shows a reading device in which a grid is arranged parallel to the scale lines in order to obtain the two-phase signals, FIG. 1 a the switching element 124, FIG. 1 b the switching element 130, FIG. 2 shows a reading device in which the phase signals are obtained by producing a self-contained network with opto-mechanical storage, FIG. 2a the switching element 172, FIG. 3 shows a reading device for a 2 mm scale with a magnetically obtained internal network and electrical storage of the phase signals, FIG. 3 a the switching element 182, FIG. 3 b the switching element 189, FIG. 4 shows a reading device in which the phase signals are generated by controlling the power network, FIG. 4 a the switching means 197, FIG. 4 b the switching means 203, FIG. 5 a display device which, without the use of mechanical correction means, allows the measured value to be clearly read off with the aid of an arrow mark.

In Fig. 1 shows the scale 1 scale lines 2 and a grid 3, by a lamp 4 by a; Lens 5 is illuminated. A lens 7 forms the grid 3 as a grid image 3 'in the image plane 8, in the two photoelectric Receivers 107 and 108 are arranged at a distance of 2/4 from one another, where A. the raster period of the Ra- designed by the lens 7; is 3 '. The photoelectric Receivers 107 and 108 are in the switching element 124 (Fig. 1 a) with the contacts 106 ' and 107 'or 108' and 109 'of a double switch 110, the other Contacts 111 and 112 with contacts 111 'and 112' of a second double switch 124 are connected, while contacts 107 "and 108" of this switch are connected to the photoelectric Receivers 107 and 108 are in communication. Contacts 116 and 117 ultimately lead to Schmitt triggers 162 and 163, which control a stepper motor 13 that has gears 15, 16 and 99 one consisting of the number rolls 22, 23 and 24 as well as a brand 25 Counter 21 drives. The scale lines 2 are of a lamp 26 through a Lens 27 is illuminated and by a lens 29 as scale lines 2 'in the image plane 8 pictured. In this a disk 125 is arranged with a spiral gap 126, which has a slope that corresponds to the distance between two scale lines in the image plane 8 corresponds. The disc 125 is mounted on a shaft 127 and is of a Synchronous motor 128 fed from an alternating current network 196 is driven. above that Spiral gap 126 is a photoelectric receiver 129 arranged with a Switching group 130 and a thyratron 131 is connected.

A synchronous motor 132, which is also fed from the alternating current network 196, drives a display disk 134 via an axis 1.33 , which has two sequences of numbers 135 and 136 in a circular arrangement. The sequence of numbers 135 begins with the value 1.00 and extends to approximately the value 1.11, is then interrupted and is only continued again by the values 23, 24 etc. up to 99, with the values 99 and 1.00 following one another. A second sequence of numbers 136 running from 00 to 30 is concentrically assigned to the values 1.00 to 30. In front of the display panel 134 there is a screen 137 with openings 138 and 139 which hide the numbers to be displayed from the sequence of numbers 135 and 136. A stroboscopic lamp 140 is arranged behind the display plate 134 at the level of the opening 138, a stroboscopic lamp 141 is arranged at the level of the opening 139 and a screen 142 is arranged between these two lamps. The stroboscopic lamps 140 and 141 are controlled by igniters 143 and 144, which in turn are connected to the anode of the thyratron 131 and a capacitor 145 and can be switched on alternately by the switching arm 146 of a double switch 147 via contacts 148, 149 and 150. Contacts 152, 153 and 154 are assigned to the second switching arm 151 of the switch 147. It completes a circuit that contains a battery 155 and a relay 156 that actuates the double switch 110.

A flash lamp 157 is also arranged behind the display plate 134. This illuminates an arcuate recess 158 located in the disk 134, which extends in sectors from the number 00 to about the number 27 and with the corresponding Position of the disc 134 the light coming from the flashlamp 157 to the photoelectric Receiver 159 lets through. The signals emitted by this excite - afterwards they were transformed into a switching element 160 - a relay 161, which is the double switch 147 actuated.

The mode of operation of the display device is as follows: The two-phase signals required to drive the motor 13 are obtained by sampling of the grating image 3 'obtained by means of the photoelectric receivers 107 and 108. When the disk 125 rotates, the spiral gap 126 runs longitudinally over the images of the scale in the image plane B. Since the width of the spiral gap 126 is exactly the same the width of the scale lines is 2 ', the spiral gap 126 comes per revolution once with a scale line image 2 'to cover. Here the photoelectric Receiver 129 a flash of light with a triangular intensity profile, the maximum of which represents the measured value. The intensity of the light flash changes themselves not if a scale line is only cut from the end of the spiral gap. In this case, the following scale line takes over with the beginning of the spiral slot in constant transition the complete and undeformed formation of the triangle shape. When the scale is stationary, the lightning event always occurs with the same phase position of the synchronous motor 128 or with the same angular position of the spiral disk 125. Becomes the benchmark 1 shifted, however, the phase position of the lightning event runs proportionally with, namely when shifted by one scale unit by an angle of 360 °. The pulses supplied by the photoelectric receiver 129 are amplified, by two-fold differentiation in the links 130 'and 130 "of the vector group 130 (Fig. 1 b) converted into narrow trigger pulses and transmitted via the thyratron 131 used to ignite the stroboscopic flash lamps 140 or 141, which mark the scales 135 or 136 of the display disc 134 illuminate. Each flash of light from the “transmitter” follows simultaneously a flash of light from one or the other stroboscopic lamp of the "receiver". Since the Disc 125 and the indicator disc 134 with the help of synchronous motors 128 and 132 phase-locked, the phase position of the "transmitter" lightning can through the C opening 138 read from the disk 134 and thus the displacement of the scale 1 by hundredths of a part of the scale unit can be determined.

The decision between the values 0.00 and 1.00 is made automatically. The flash lamp 157 lights up with the flash lamp 140 or 141 in time and brings the relay 161 to respond when flash pulses are received through the recess 158. The selection process proceeds as follows: The instantaneous measured value may, as shown in FIG. 1 is shown to lie at 85. The photoelectric receiver 159 receives no light, the relay 161 is in the rest position. As a result, the contacts 149 and 150 are connected to one another by the switching arm 146 , and the strobe lamp 141 is short-circuited. The strobe lamp 140, on the other hand, illuminates the scale 135 and makes the value 85 visible. If the scale 1 is now pushed further, the values 86, 87 etc. and finally the value 1.00 appear in the opening 138. This means that one unit is to be added to the measured value which the counter 21 displays. At the numerical value 1.01, for example, the photoelectric receiver 159 receives light through the recess 158, excites the relay 161 and thus turns the switching arms 146 and 151 of the switch 147 so that the contacts 148 and 150 or 153 and 152 are connected to one another . As a result, the lamp 140 goes out, but the lamp 141 ignites and makes the value 01 of the number sequence 136 visible. At the same time, the relay 1.56 actuates the double switch 110, which determines the direction of correction and switches the counter 21 forward by one unit. The stroboscopic lamp 141 remains in operation until about the value 30 (end of the recess 158); then the stroboscopic lamp 140 takes over the display again.

In the embodiment according to FIG. 2 sits on the disc 134, which is designed here without a recess, axle 133 carrying a further disk 164 with a semicircular slot 165 and another recess 166 that according to the shape and angular position of the recess 158 according to FIG. 1 corresponds. The flash lamp 157 illuminates the disk 164 from behind through a lens 167 and sends light to the photoelectric ones arranged in front of the slot 165 and offset from one another by 90 ° Receiver pairs 168, 169 and 170, 171 as well as on those arranged in front of the recess 166 photoelectric receiver 159. A switching arrangement 172 (Fig. 2a) controls both the stepping motor 13, which drives the counter 21 via the gears 15, 16 and 99, as well as the correction device by means of a relay 14. The photoelectric Receivers 168 and 169 act on a bistable multivibrator 173 in such a way that that pulses of the photoelectric receiver 168 the multivibrator 173 in one Position, on the other hand, impulses from the receiver 169 tilt into the other position. Corresponding The photoelectric receivers 170 and 171 act on the multivibrator 174. The voltages between the multivibrators 173 and 174 form upon displacement of the scale 1 a cycle of four in the sense of a rotating field, in which, however four steps are assigned to each scale unit. But there in the special embodiment according to FIG. 2 if only two steps per scale unit are desired, the cycle of four becomes through two Eccles-Jordan stages 175 and 176 (bistable flip-flops with pulse control, cause the frequency to halve) extended to double the scale unit. With the two conductors of the stepping motor 13 is equipped with a pull-in delay 55 Relay 14 connected.

The correction device consists of two electromagnetic coils 49 and 50, into which a T-shaped core 48 is immersed, which carries a fork 105 and which is fastened to the two coils 49 and 50 by means of springs 51 and 52. The winding of the coil 49 is connected to the contact 154 of the switch 147, and the winding of the coil 50 is connected to the contact 153 . The other ends of the windings of the electromagnetic coils lead to a source 53 which can be connected to the contact 152 of the switch 147 via the switch 54 actuated by the relay 14.

The way the reading device works is completely analogous to the way it works the reading device according to FIG. 1 and differs only in the extraction the two-phase signals and the display of the corrected value of the unity roller 22 of the counter 21 through the fork 105. The arrangement is supplemented by a plane parallel plate 177, which is located in the projection beam path of the scale and which, for example can be pivoted by means of a knurled handle 178. By pivoting this Plane-parallel plate can always be achieved that in the opening 139 the number 00 appears and is illuminated.

In the embodiment according to FIG. 3 a scale 1 a is used, in which the distance between the scale lines 2a is twice as large as that of the units of the coarse counter 21 is assigned length unit. On axis 127 of the synchronous motor 128 sits a disk 125 'with a spiral gap 126', which is designed with two threads and its slope is half the size of the scale line spacing in the scale image plane 8 a is. The spatial extent of the photoelectric associated with this disk Receiver 129 'is equal to the distance between the scale line images 2a'. As a result of two-course Aus-C, leadership of the spiral gap 126 'is repeated the position of the flashes of light to the phase position of the synchronous motor 128 or to the angular position of the disc 125 'after a shift of the scale la by half Line spacing. The pulses supplied by this scanning device already ignite the stroboscopic lamp 140 or 141 as described.

An indicator disk 134 ', which sits on the axis 133 of the synchronous motor 132, carries the indicator disk 134, the two scales 135 and 136 and a magnetic mark 179, the magnetic heads 180 and 181, which are offset by 180 ° from one another, in the same arrangement as in the previous exemplary embodiments is scanned. The pulses generated in the magnetic heads 180 and 181 are fed to a switching arrangement 182, which in turn controls the stepping motor 13. The stepping motor is connected via the gears 15 and 16 to a differential gear consisting of bevel gears 17, 18 and 19 which is mounted in a bracket 20 and which drives the counter 21. The magnetic mark 179 is also scanned by a magnetic head 183 which is arranged offset by 90 ° with respect to the magnetic heads 180 and 181 and supplies its pulses to a switching arrangement 184 which in turn actuates the relay 161.

As shown in FIG. 3 a shows two bistable multivibrators 185 and 185 ', which are tilted by the pulses supplied by the magnetic heads 180 and 181 and generate square-wave voltages which are phase-shifted by 90 °, the frequency of which is equal to half the rotational frequency of the disk 134'. These phase-shifted square-wave voltages are fed to phase-sensitive switches 186 and 186 ', which are controlled by the pulses of the photoelectric receiver 129' and thus transmit the instantaneous value of the square-wave voltages to two memories 187 and 187 '. The output voltages of these memories form a two-phase rotating field which, when the scale la is shifted by one scale line spacing (double length unit), runs through a four cycle. The currents of the downstream DC amplifiers 188 and 188 'then drive the stepping motor 13 and, through the relay 14, influence the correction device.

Similarly, in switching arrangement 184 (FIG. 3 b), a monostable is produced Multivibrator 190, which is designed so that after about a third of the revolution of the disk 134 'tilts back to its stationary state, corresponding to that of Magnetic head 183 supplied signals a square wave voltage. This square wave voltage is via a phase-sensitive switch 191, which is also controlled by the Innpuls of the photoelectric receiver 129 'is controlled, fed to a memory 192. The instantaneous voltage value stored here controls via a direct current amplifier 193 the relay 161, optionally equipped with a pick-up delay 16Y.

Otherwise, the further arrangement corresponds to the dei in FIG. 2 shown Arrangement. The difference between the two arrangements according to FIGS. 2 and 3 lies in the generation and electrical storage of the correction signals as well the two-phase signals to drive the stepper motor.

In Fig. 4 shows a further exemplary embodiment in which in contrast to the in FIG. 3 shows the correction signals and the two-phase signals can be obtained from an alternating current network 196 to drive the stepping motor 13, in the usual way the synchronous motor 128 with the disk 125 'and the synchronous motor 132 with the indicator disc 134 feeds.

In a switching arrangement 197 (FIG. 4a), the alternating voltage supplied by the alternating current network 196 is fed to a bistable multivibrator 198 and, parallel thereto, after the phase has been rotated by 180 ° by means of a phase shifter 199 ', to a bistable multivibrator 198'. At the outputs of these two multivibrators, two square-wave voltages, phase-shifted by 90 °, occur at half the mains frequency and are fed to the phase-sensitive switches 200 and 200 '. The switches 200 and 200 'are controlled by the pulses from the photoelectric receiver 129' after they have passed through the pulse shaping stage 130, and the instantaneous values of the phase-shifted square-wave voltages are thereby fed to two memories 201 and 201 '. The output voltages of these memories 201 and 201 'form a two-phase rotating field which, when the scale 1 a is shifted by one scale line spacing (double the length unit), runs through a cycle of four. The currents of the downstream direct current amplifiers 202 and 202 'act on the stepping motor 13 and actuate the correction relay 14 equipped with the pick-up delay 55.

The direction of correction is obtained by means of the switching arrangement 203 (FIG. 4b). After the phase has been rotated by 90 °, the voltage of the alternating current network 196 is fed by a phase shifter 204 to a monostable multivibrator 205 which is designed so that it tilts back into its steady state after about a third of the revolution of the display disk 134. The square-wave voltage thus produced is fed to a store 207 via a phase-sensitive switch 206, which is also controlled by the pulses from the photoelectric receiver 129 '. The instantaneous voltage stored therein controls, via a direct current amplifier 208, the relay 161, optionally equipped with the pull-in delay 161 ', which actuates a switch 147'.

In this exemplary embodiment, the display device has only one stroboscopic lamp 140 ', which is ignited by the photoelectric receiver 129' via the thyratron 131 and an ignition device 143 '. It also has a front of the counter 21 and the display disc 134, provided with windows 210, 211 and 212 aperture 209, which is supported by the magnet coils 49 and 50 by means of the T-shaped core 48 by a digit height of the counter 21 and the fine scales 135 and 136 can be moved. A mask 213 with windows 214 and 215 is arranged in front of the diaphragm 209. The window 214 is designed in such a way that the two equal digits of the unit roll 22 of the counter 21 are visible in half position, as well as one digit each of the number rolls 23 and 24. The diaphragm window 210, the height of which corresponds to approximately s / 2 digit heights, lies behind the mask window 214. The diaphragm windows 211 and 212, which are offset from one another by one digit height, make numbers on one or the other of the two fine dials 135 depending on the position of the diaphragm 209 or 136 visible through the mask window 215.

The correction process takes place in the previous exemplary embodiments analogous way. One of the two fine scales 135 and is switched off 136 not by switching over two strobe lamps, but by shifting them the aperture 209.

F i g. 5 finally shows an embodiment in which the display of the corrected value takes place without mechanical aids. The scales 135 'and 136 'of an indicator disc 134 ", which in contrast to the scales 135 and 136 by one Are offset from each other, two stroboscope lamps 140 and 1.41 are assigned, in the in the exemplary embodiments F i g. 1, 2 or 3 executed manner ignited and can be switched. In front of the display disc 134 ″ and the counter 21 is a Mask 216 arranged with windows 217, 218 and 219 as well as with arrow markings 220, 221, 222 and 223 is provided. The window 217 gives the number rollers 22, 23 and 24 after the in FIG. 4 described type freely, the window 218 a section the scale 136 'and the window 219 a section of the scale 135'.

The arrow marking allows the measured values to be read clearly. In the arrangement according to FIG. 5, for example, let the stroboscopic lamp 140 sitting behind the window 219 flash so that the value 1.01 is displayed in the window 219. With the aid of the arrow 220, the number 5 on the unit roll 22 of the counter 21 is assigned to the fine value. The result is the value 375 -I- 1.01 = 376.01. If, however, the stroboscopic lamp 141 flashes - the arrangement is adjusted analogously to the previous exemplary embodiments so that the lamps are switched over at about fine values 01 and 30 --- the reading 376.01 follows immediately with the aid of arrow 223. If a number of the unit roller 22 is in a row with the numbers of the other rollers, the arrow 221 or 222 provides the assignment between coarse and fine display.

It should also be mentioned that instead of the disk shown with a spiral gap also a corresponding drum or another one that generates a tilting vibration Component can be used.

Claims (7)

Claims: 1. Device for the numerical display of measured values on a non-numbered measuring graduation, in which a motor driven according to the two-phase principle is provided to control a counter that counts the units of the scale, and which contains means for fine measurement that control a correction device, according to patent application L 33298 IXb / 42d (German Auslegeschrift 1187 383) and patent application L 34070 IXb / 42d (German Auslegeschrift 1266519), characterized in that a scanning device is present as the means for fine measurement, which is connected to a display device carrying a sequence of numbers, and that the from the pulses supplied to the scanning device control at least one stroboscopic lamp in such a way that the flash lamp lights up exactly when the number of the number sequence representing the intermediate value has reached a certain position in front of the stroboscopic lamp. 2. Apparatus according to claim 1, characterized in that the scanning device a rotating disc or drum provided with a spiral gap and a stationary, photoelectric receiver that interacts with it are. 3. Apparatus according to claim 1, characterized in that the display device has a, for example, disk-shaped, rotatable carrier on which side by side two sequences of numbers are attached for the fine display of the measurement result. 4. Device according to claim 2, characterized by a scale in which the line spacing is Unit of length corresponds to the scale, as well as by a disk, in which the pitch of the spiral gap corresponds to the unit of length of the scale. 5. Device according to claim 2, characterized by a scale in which the line spacing is two Includes units of length of the scale, as well as by a scanning disc in which the pitch of the spiral gap corresponds to two units of length on the scale. 6. Device according to claims 1 to 5, wherein the scale with a grid is connected, the grid constant of which is single or double the line spacing is, characterized in that the generation of the two-phase signals for the Coarse counting in a manner known per se by photoelectric scanning of the grid with two or four offset photoelectric receivers he follows. 7. Device according to claims 1 to 5, characterized in that the generation of the two-phase signals for the coarse counting in a manner known per se by photoelectric scanning of the scale with two or four offset against each other arranged photoelectric receivers takes place. B. Device according to the claims 1 to 5, characterized in that the two-phase signals are generated by sampling one with control marks rotating synchronously with the scanning or display device provided disc takes place. 9. Apparatus according to claim 8, characterized in that that the tax stamps are given in the form of recesses by a flash lamp are illuminated in the rhythm of the pulses supplied by the scanning device, and that those received by photoelectric receivers through the recesses Light pulses using multivibrator levels and optionally Eccles-Jordan levels can be used to generate two-phase signals. 10. Apparatus according to claim 9, characterized in that a semicircular slot and as a tax stamp four photoelectric receivers offset by 90 ° are provided for scanning are. 11. The device according to claim 8, characterized in that the tax stamp is designed as a magnetic mark that is scanned by magnetic heads, and that the Signals supplied by the magnetic heads are phase-shifted in multivibrator stages Vibrations generated by the pulses supplied by the scanning device become effective as two-phase signals by means of phase-sensitive storage elements. 12. Device according to claims 1 to 5, characterized in that the generation the two-phase signals for the coarse counting takes place through an alternating current network, with which on the one hand the scanning or display device is phase-locked and connected the other hand, a first phase-sensitive switch directly and a second phase-sensitive switch is supplied with a 90 ° phase shift, and that this phase-sensitive switch, which electrical storage elements are connected downstream are actuated in the rhythm of the pulses supplied by the scanning device. 13. Device according to one of claims 1 to 4, characterized in that as Motor for driving the counter is a stepper motor whose position the position of the counter is assigned in such a way that two digits are on the unit roll are visible as equivalent if the position of the stepper motor is the last and corresponds to the first quarter of two consecutive scale units, and that also a correction device to read the digit of the unit roll in Depends on the intermediate value. 14. Apparatus according to claim 13, characterized characterized in that the correction device has a first, optionally with pull-in delay Contains relay equipped with the photoelectric receivers for the Generation of the two-phase signals provided scanning device is connected and therefore responds when the position of the stepper motor of the ambiguous position of the One roll of the counter corresponds, and that a second, a double switch controlling relay is present, whose response by photoelectric or magnetic scanning corresponding brands is controlled with the scanning or display device circulate synchronously. 15. Apparatus according to claim 13, characterized in that the correction device contains a solenoid, which is known per se Way a differential gear or arranged between stepper motor and counter actuates a pivoting shutter located above the single roller. 16. Device according to Claim 13, characterized in that the correction device is a switching magnet contains, which controls a diaphragm interacting with a fixed mask, which, provided with several windows, both the counter and the display disc assigned. 17. The device according to claim 13, characterized in that the Correction device from a fixed, provided with several windows Orifice, which is equipped with reference pointers. 18. Device according to the Claims 3 and 14, characterized in that the second relay simultaneously a toggle switch for alternately turning on two, the two sequences of numbers of the Controls display device associated stroboscopic lamps. 19. Apparatus according to claim 1, characterized in that the scanning device is a device known per se for zero setting, for example a pivotable plane-parallel plate contains.